Test and Measurement Division Operating Manual VECTOR NETWORK ANALYZER ZVR / ZVRE / ZVRL 1127.8551.61/.62 1127.8551.51/.52 1127.8551.41 ZVC / ZVCE 1127.8600.60/.61/.62 1127.8600.50/.51/.52 ZVM 1127.8500.60 ZVK 1127.8651.60 Volume 2 Operating Manual consists of 2 volumes Printed in the Federal Republic of Germany 1127.8700.
ZVx Tabbed Divider Overview Volume 1 Volume 2 Contents Index Contents Index Data Sheet Supplements Safety Instructions Certificate of Quality EC-Certificate of Conformity Support Center Address List of R&S Representatives Safety Instructions Certificate of Quality EC-Certificate of Conformity Support Center Address List of R&S Representatives Tabbed Divider Tabbed Divider 1 Preparation for Use 1 Remote Control 2 Manual Operation 2 Maintenance and Troubleshooting 3 Testing the Rated Specif
ZVx Contents Contents 3 Remote Control .......................................................................................................................... 3.1 3.1 Introduction............................................................................................................................ 3.1 3.2 Brief Instructions................................................................................................................... 3.1 3.3 Switchover to Remote Control ...................
Contents ZVx 3.6.3.5 3.6.3.6 3.6.3.7 3.6.3.8 3.6.3.9 CALCulate:MARKer Subsystem ..................................................................... 3.29 CALCulate:MATH Subsystem ........................................................................ 3.38 CALCulate:SMOothing Subsystem ................................................................ 3.39 CALCulate:TRANsform Subsystem ............................................................... 3.40 CALCulate:UNIT Subsystem ............................
ZVx Contents 3.8.3.1 3.8.3.2 3.8.3.3 3.8.3.4 3.8.3.5 3.8.3.6 Status Byte (STB) and Service Request Enable Register (SRE) ................. 3.152 IST Flag and Parallel Poll Enable Register (PPE) ........................................ 3.153 Event-Status Register (ESR) and Event-Status-Enable Register (ESE)...... 3.153 STATus:OPERation Register ....................................................................... 3.154 STATus:QUEStionable-Register .........................................................
Contents ZVx 4 Maintenance and Troubleshooting .................................................................................... 4.1 4.1 Maintenance........................................................................................................................... 4.1 4.1.1 Mechanical Maintenance............................................................................................... 4.1 4.1.2 Electrical Maintenance .........................................................................
ZVx Contents Contents 5 Testing the Rated Specifications ........................................................................................ 5.1 5.1 Measuring Instruments and Accessories (ZVR, ZVRE, ZVRL).......................................... 5.1 5.2 Test Sequence (ZVR, ZVRE, ZVRL)...................................................................................... 5.2 5.2.1 Testing the Generator Specifications ............................................................................ 5.
Contents ZVx 5.5.3 Testing the Test Set Specifications ............................................................................. 5.63 5.5.3.1 5.5.3.2 5.5.3.3 5.5.3.4 5.6 Matching to PORT1 and PORT2 .................................................................... 5.63 Directivity ........................................................................................................ 5.63 Testing the Attenuators .................................................................................. 5.
ZVx Contents Annex A - Interfaces ......................................................................................................................A.1 A.1 IEC Bus Interface (SCPI IEC625, SYSTEM BUS).................................................................A.1 Interface Characteristics..........................................................................................................A.1 Bus Lines ............................................................................................
Contents ZVx Annex B – List of Error Messages ...........................................................................................B.1 B.1 SCPI-Specific Error Messages .............................................................................................B.1 Annex C – List of Commands ....................................................................................................C.1 Annex D – Programming Examples ...........................................................................
ZVx Figures Figures Fig. 3-1 Tree structure of the SCPI command systems: The SENSe system ...................................... 3.9 Fig. 3-2 Model of the instrument in the case of remote control by means of the IEC bus ................ 3.146 Fig. 3-3 The status register model .................................................................................................... 3.149 Fig. 3-4 Overview over the status registers .................................................................................
Tables ZVx Tables Table 3-1 Synchronisation using *OPC *OPC? and *WAI................................................................. 3.148 Table 3-2 Meaning of the bits used in the status byte ....................................................................... 3.152 Table 3-3 Meaning of the bits used in the event status register ........................................................ 3.153 Table 3-4 Meaning of the bits used in the STATus.OPERation register...........................................
ZVx Index Index Note: All softkeys are listed with their names. The page numbers 2.xxx refer to the detailed description of the softkeys in chapter 2. Generally, the number of the page in chapter 3 containing the equivalent remote control command is given in addition. A list of softkeys and equivalent remote control commands or command sequences is given in section 3.9. Annex C contains a list of all remote control commands. APPLY CAL (TOSM)..........................................2.313, 3.
Index ZVx BOTH PORTS (REFL NORM, ZVR) .................. 2.335, 3.93 BRIGHTNESS ............................................................ 2.288 Broadband termination................................................ 2.304 COLORS.................................................................... 2.287 COLORS (selection table).......................................... 2.289 COM PORT 1........................................2.144, 3.136, 3.137 COM PORT 2........................................2.144, 3.
ZVx Index DATA SET LIST (RECALL) ........................................ 2.179 DATA SET LIST / CONTENTS (RECALL) (selection table) ................................................................................... 2.179 DATA SET LIST / CONTENTS (SAVE) (selection table) ................................................................................... 2.170 DATA TO MEMORY ........................................ 2.292, 3.141 Date input ....................................................................
Index ZVx ELECTRICAL LENGTH (OFFSET).................... 2.372, 3.97 Electrostatic discharge..................................................1.20 Enable Front panel keys................................................... 2.182 ENABLE ALL ITEMS (RECALL) ........................ 2.181, 3.71 ENABLE ALL ITEMS (SAVE) ............................ 2.172, 3.71 ENABLE NEW OPTION ............................................. 2.149 Enhancement label .......................................................2.53 ARB...
ZVx Index GATE START ................................ 2.105, 2.114, 3.20, 3.41 GATE STOP.................................. 2.105, 2.114, 3.20, 3.42 Generator power calibration........................................ 2.355 GOTO POINT # (EDIT POWER LOSS LIST) ............. 2.371 GOTO POINT # (SENSOR CAL FACTOR) ................ 2.367 GOTO SECTION # ..................................................... 2.240 GOTO SEGMENT # ................................................... 2.281 GPIB ADDRESS................
Index ZVx LIN SWEEP.......................................... 2.193, 3.104, 3.113 Lin/Log display ....................................................................2.51 LINE ................................................................ 2.201, 3.144 LINE 1 ............................................................... 2.310, 3.92 LINE 2 ............................................................... 2.310, 3.92 LINE SECTIONS (selection table) .............................. 2.
ZVx Index frequency sweep .................................................. 2.138 frequency-converting measurements.................... 2.117 mixer measurements ............................................ 2.119 power sweep ........................................................ 2.139 reference mixer .................................................... 2.140 segmented sweep ................................................ 2.194 single point measurement..................................... 2.
Index ZVx PORT 2 (REFL NORM, ZVR) ..................................... 2.335 PORT1/PORT2........................................................... 2.372 POWER........................................................... 2.208, 3.115 Power added efficiency............................................... 2.264 Power loss list ............................................................ 2.369 POWER LOSS LIST (selection table) ......................... 2.370 POWER MTR CONFIG ........................ 2.365, 3.
ZVx Index display ........................................................... 2.52, 2.53 ordinate ..................................................................2.66 radial ......................................................................2.69 reference value..................................................... 2.273 SCPI-standard ................................................................3.1 block data...............................................................3.13 boolean parameters......
Index ZVx Softkey ENABLE DEV1 / DEV2......................................... 2.163 GENERAL SETUP ............................................... 2.142 MONITOR CONNECTED ..................................... 2.147 SETTINGS DEVICE 1/2 ....................................... 2.162 Softkey display ....................................................................2.59 EXT SRC CONFIG ............................................... 2.130 IEC/IEEE bus .........................................................2.
ZVx Index TOM-X............................................................... 2.314, 3.93 TOSM ................................................................ 2.312, 3.93 TOSM (ZVRE) ................................................... 2.318, 3.93 TOUCHSTONE ................................................. 2.173, 3.53 Trace ............................................................................2.58 TRACE (key) .............................................................. 2.292 TRACE MATH function.
Important Hints before Operation: For all instruments: • The directory C:\R_S\INSTR and its subdirectories are reserved for system software. Never modify this directory in any way, otherwise the functioning of the instrument will be impaired. • Aborting a hardcopy is not possible when printout is in progress. Print jobs in the queue can be deleted before printout has been started by pressing the HARDCOPY START key until the message "Hardcopy in progress. Abort?" is displayed.
Patent Information This product contains technology licensed by Marconi Instruments LTD. under US patents 4609881 and 4870384 and under corresponding patents in Germany and elsewhere. Please note the safety instructions on the next sheet ! 1043.0009.50 S.
Before putting the product into operation for the first time, make sure to read the following Safety Instructions Rohde & Schwarz makes every effort to keep the safety standard of its products up to date and to offer its customers the highest possible degree of safety. Our products and the auxiliary equipment required for them are designed and tested in accordance with the relevant safety standards. Compliance with these standards is continuously monitored by our quality assurance system.
Safety Instructions Observing the safety instructions will help prevent personal injury or damage of any kind caused by dangerous situations. Therefore, carefully read through and adhere to the following safety instructions before putting the product into operation. It is also absolutely essential to observe the additional safety instructions on personal safety that appear in other parts of the documentation.
Safety Instructions 4. If products/components are mechanically and/or thermically processed in a manner that goes beyond their intended use, hazardous substances (heavy-metal dust such as lead, beryllium, nickel) may be released. For this reason, the product may only be disassembled, e.g. for disposal purposes, by specially trained personnel. Improper disassembly may be hazardous to your health. National waste disposal regulations must be observed. 5.
Safety Instructions 19. If a product is to be permanently installed, the connection between the PE terminal on site and the product's PE conductor must be made first before any other connection is made. The product may be installed and connected only by a skilled electrician. 20. For permanently installed equipment without built-in fuses, circuit breakers or similar protective devices, the supply circuit must be fused in such a way that suitable protection is provided for users and products. 21.
Por favor lea imprescindiblemente antes de la primera puesta en funcionamiento las siguientes informaciones de seguridad Informaciones de seguridad Es el principio de Rohde & Schwarz de tener a sus productos siempre al día con los estandards de seguridad y de ofrecer a sus clientes el máximo grado de seguridad. Nuestros productos y todos los equipos adicionales son siempre fabricados y examinados según las normas de seguridad vigentes.
Informaciones de seguridad Tener en cuenta las informaciones de seguridad sirve para tratar de evitar daños y peligros de toda clase. Es necesario de que se lean las siguientes informaciones de seguridad concienzudamente y se tengan en cuenta debidamente antes de la puesta en funcionamiento del producto. También deberán ser tenidas en cuenta las informaciones para la protección de personas que encontrarán en otro capítulo de esta documentación y que también son obligatorias de seguir.
Informaciones de seguridad seguridad (control a primera vista, control de conductor protector, medición de resistencia de aislamiento, medición de medición de la corriente conductora, control de funcionamiento). 3. Como en todo producto de fabricación industrial no puede ser excluido en general de que se produzcan al usarlo elementos que puedan generar alergias, los llamados elementos alergénicos (por ejemplo el níquel).
Informaciones de seguridad 12. No utilice nunca el producto si está dañado el cable eléctrico. Asegure a través de las medidas de protección y de instalación adecuadas de que el cable de eléctrico no pueda ser dañado o de que nadie pueda ser dañado por él, por ejemplo al tropezar o por un golpe de corriente. 20.
Informaciones de seguridad 27. Baterías y acumuladores no deben de ser expuestos a temperaturas altas o al fuego. Guardar baterías y acumuladores fuera del alcance de los niños. Si las baterías o los acumuladores no son cambiados con la debida atención existirá peligro de explosión (atención celulas de Litio). Cambiar las baterías o los acumuladores solamente por los del tipo R&S correspondiente (ver lista de piezas de recambio). Baterías y acumuladores son deshechos problemáticos.
EC Certificate of Conformity Certificate No.: 2000-05, page 1 This is to certify that: Equipment type Stock No. Designation ZVC ZVCE ZVK ZVM ZVR ZVRE ZVRL 1127.8600.60/.61/.62 1127.8600.50/.51/.52 1127.8651.60 1127.8500.60 1127.8551.61/.62 1127.8551.51/.52/.55 1127.8551.
EC Certificate of Conformity Certificate No.: 2000-05, page 2 This is to certify that: Equipment type Stock No. Designation ZVK-B21 ZVK-B22 ZVK-B23 ZVK-B24 ZVM-B21 ZVM-B22 ZVM-B23 ZVM-B24 ZVR-B1 ZVR-B2 ZVR-B8 ZVR-B10 ZVR-B14 ZVR-B21 ZVR-B22 ZVR-B23 ZVR-B24 ZVR-B26 FSE-B16 FSE-B17 1128.1409.11 1128.1409.21 1128.1409.12 1128.1409.22 1128.1009.11 1128.1009.21 1128.1009.12 1128.1009.22 1044.0625.02 1044.1009.02 1086.0000.02 1106.6495.xx 1106.7510.02/.03 1044.0025.11 1044.0025.21 1044.0025.12/.31 1044.0025.
ZVx 3 Introduction/Brief Instructions Remote Control 3.1 Introduction The instrument is equipped with two IEC/IEEE bus interfaces according to standard IEC 625.1/IEEE 488.1 and two RS-232 interfaces. Either the connector labeled SCPI IEC625 (the upper IEC/IEEE bus interface) or both of the RS-232 interfaces can be used for remote control of the instrument.
Switchover to Remote Control ZVx 3.3 Switchover to Remote Control On power-on, the instrument is always in the manual operating state ("LOCAL" state) and can be operated via the front panel. It is switched to remote control ("REMOTE" state) IEC/IEEE bus as soon as it receives an addressed command from a controller. RS-232 as soon as it receives the command "@REM" from a controller. RSIB as soon as it receives an addressed command from a controller.
ZVx 3.3.1.3 Switchover to Remote Control Return to Manual Operation Return to manual operation is possible via the front panel or the IEC bus. ½ Press the LOCAL key. Manually: Note: – Before switchover, command processing must be completed as otherwise switchover to remote control is effected immediately. – The LOCAL key can be disabled by the universal command LLO (see annex A) in order to prevent unintentional switchover. In this case, switchover to manual mode is only possible via the IEC bus.
Switchover to Remote Control 3.3.2.3 ZVx Return to Manual Operation Return to manual operation is possible via the front panel or via RS-232 interface. ½ Press the LOCAL key. Manually: Note: – Before switchover, command processing must be completed as otherwise switchover to remote control is effected immediately. – The LOCAL key can be disabled by the universal command LLO (see annex A) in order to prevent unintentional switchover.
ZVx 3.3.3.2 Switchover to Remote Control Unix Environment In order to access the measuring equipment via the RSIB interface, copy the librsib.so.X.Y file to a directory for which the control application has read rights. X.Y in the file name indicates the version number of the library, for example 1.0. The librsib.so.X.Y library is created as a shared library. The applications using the library have nothing to do with versions. They simply link the library with the lrsib option.
Messages ZVx 3.4 Messages The messages transferred via the data lines of the IEC bus or via the RSIB Interface (see annex A) can be divided into two groups: – interface messages and – device messages. For the RS-232 interface, no interface messages are defined. 3.4.1 IEC/IEEE bus Interface Messages Interface messages are transferred on the data lines of the IEC bus, the "ATN" control line being active.
ZVx 3.4.3 Messages Device Messages (Commands and Device Responses) Device messages are transferred on the data lines of the IEC bus, the "ATN" control line not being active. ASCII code is used. The device messages are more or less equal for the 2 interfaces (IEC/IEEE bus and RS-232). A distinction is made according to the direction in which they are sent on the IEC bus: – Commands are messages the controller sends to the instrument. They operate the device functions and request informations.
Structure and Syntax of the Device Messages 3.5 Structure and Syntax of the Device Messages 3.5.1 SCPI Introduction ZVx SCPI (Standard Commands for Programmable Instruments) describes a standard command set for programming instruments, irrespective of the type of instrument or manufacturer. The goal of the SCPI consortium is to standardize the device-specific commands to a large extent. For this purpose, a model was developed which defines the same functions inside a device or for different devices.
ZVx Structure and Syntax of the Device Messages Device-specific commands Hierarchy: Device-specific commands are of hierarchical structure (see Fig. 3-1). The different levels are represented by combined headers. Headers of the highest level (root level) have only one key word. This key word denotes a complete command system. Example: This key word denotes the command system SENSe.
Structure and Syntax of the Device Messages Optional key words: ZVx Some command systems permit certain key words to be optionally inserted into the header or omitted. These key words are marked by square brackets in the description. The full command length must be recognized by the instrument for reasons of compatibility with the SCPI standard. Some commands are considerably shortened by omitting these optional key words.
ZVx 3.5.3 Structure and Syntax of the Device Messages Structure of a Command Line A command line may consist of one or several commands. It is terminated by a , a with EOI or an EOI together with the last data byte. Quick BASIC automatically produces an EOI together with the last data byte. Several commands in a command line are separated by a semicolon ";". If the next command belongs to a different command system, the semicolon is followed by a colon.
Structure and Syntax of the Device Messages 3.5.5 ZVx Parameters Most commands require a parameter to be specified. The parameters must be separated from the header by a "white space". Permissible parameters are numerical values, Boolean parameters, text, character strings and block data. The type of parameter required for the respective command and the permissible range of values are specified in the command description (see Section 3.6). Numerical values Numerical values can be entered in any form, i.
ZVx Structure and Syntax of the Device Messages Text Text parameters observe the syntactic rules for key words, i.e. they can be entered using a short or long form. Like any parameter, they have to be separated from the header by a white space. In the case of a query, the short form of the text is provided. Example: Setting command: INPut:COUPling Query: INPut:COUPling? Strings GROund Response GRO Strings must always be entered in quotation marks (’ or ").
Description of Commands ZVx 3.6 Description of Commands 3.6.1 Notation In the following sections, all commands implemented in the instrument are first listed in tables and then described in detail, separated according to the command system. The notation corresponds to the one of the SCPI standards to a large extent. The SCPI conformity information can be taken from the individual description of the commands.
ZVx Description of Commands Special characters | A selection of key words with an identical effect exists for several commands. These key words are indicated in the same line, they are separated by a vertical stroke. Only one of these key words has to be indicated in the header of the command. The effect of the command is independent of which of the key words is indicated. Example:SENSe:FREQuency:CW|:FIXed The two following commands of identical meaning can be formed.
Description of Commands ZVx These indications mark parameters which may be entered as numeric values or be set using specific keywords (character data). The keywords given below are permitted: MINimum This keyword sets the parameter to the smallest possible value. MAXimum This keyword sets the parameter to the largest possible value. DEFault This keyword is used to reset the parameter to its default value. UP This keyword increments the parameter value.
ZVx 3.6.2 Common Commands Common Commands The common commands are taken from the IEEE 488.1 (IEC 625-2) standard. Same commands have the same effect on different devices. The headers of these commands consist of an asterisk "*" followed by three letters. Many common commands refer to the status reporting system which is described in detail in Section 3.8.
Common Commands ZVx *CAL? CALIBRATION QUERY triggers a calibration of the instrument and subsequently query the calibration status. Any responses > 0 indicate errors. *CLS CLEAR STATUS sets the status byte (STB), the standard event register (ESR) and the EVENt-part of the QUEStionable and the OPERation register to zero. The command does not alter the mask and transition parts of the registers. It clears the output buffer. *ESE 0...
ZVx Common Commands *PRE 0 to 255 PARALLEL POLL REGISTER ENABLE sets parallel poll enable register to the value indicated. Query *PRE? returns the contents of the parallel poll enable register in decimal form. *PSC 0 | 1 POWER ON STATUS CLEAR determines whether the contents of the ENABle registers is maintained or reset in switching on. *PSC = 0 causes the contents of the status registers to be maintained.
CALCulate Subsystem 3.6.3 ZVx CALCulate Subsystem The CALCulate subsystem contains commands for converting instrument data, transforming and carrying out corrections. These functions are carried out subsequent to data acquisition, i.e., following the SENSe subsystem. CALCulate1...4 selects the corresponding channel CH1...CH4. 3.6.3.1 CALCulate:FILTer - Subsystem The CALCulate:FILTer subsystem defines how filter functions are applied to the measured data sets. COMMAND PARAMETER CALCulate<1..
ZVx CALCulate Subsystem CALCulate[1...4]:FILTer[:GATE]:TIME:SPAN This command defines the span of the gate. CALCulate[1...4]:FILTer[:GATE]:TIME:SPAN Syntax: "CALC:FILT:TIME:SPAN 50ms" Example: Features: *RST-Wert: SCPI: 1 ns conforming CALCulate[1...4]:FILTer[:GATE]:TIME:CENTer This command defines the center value for the gate. CALCulate[1...
CALCulate Subsystem 3.6.3.2 ZVx CALCulate:FORMat Subsystem The CALCulate:FORMat subsystem specifies the display format of the measured data. COMMAND PARAMETER CALCulate<1...4> :FORMat UNIT COMMENT COMPlex|MAGNitude|PHASe| UPHase|REAL|IMAGinary|SWR| GDELay|L|C CALCulate[1 to 4]:FORMat This command defines in which format the complex measured quantity is displayed. Syntax: CALCulate[1...4]:FORMat Example: "CALC:FORM IMAG" Features: *RST value: SCPI: 1043.0009.
ZVx 3.6.3.3 CALCulate Subsystem CALCulate:GDAPerture Subsystem The CALCulate:GDAPerture - subsystem defines the parameters for the group delay and the aperture. COMMAND PARAMETER UNIT COMMENT CALCulate<1..4> GDAPerture :MODE [:SPAN] :SCOunt STEP | FREQuency HZ CALCulate[1...4]:GDAPerture:MODE This command switches between the aperture defined as a number of points (STEP) or as a fixed frequency value.. Syntax: CALCulate[1...
CALCulate Subsystem 3.6.3.4 ZVx CALCulate:LIMit Subsystem The CALCulate:LIMit subsystem comprises the limit lines and the corresponding limit checks. COMMAND PARAMETER UNIT COMMENT CALCulate<1..4> :LIMit<1...8> :STATe :RDOMain :COMPlex :FORMat :SPACing :CONTrol [:DATA] :DOMain :SHIFt :CENTer :SHIFt :UPPer [:DATA] S | SINV | Y | Z | YREL | ZREL COMPlex | MAGNitude | PHASe | REAL | IMAGinary | SWR | GDELay | L | C LINear | LOGarithmic | DB | SIC ,..
ZVx CALCulate Subsystem CALCulate[1...4]:LIMit[1...8]: RDOMain:COMPlex This command defines the complex conversion of the measured value belonging to the limit line. CALCulate[1...4]:LIMit[1...8]: RDOMain:COMPlex S | SINV | Y | Z | YREL | Syntax: ZREL "CALC:LIM:RDOM:COMP Y" Example: Features: *RST value: SCPI: – device-specific CALCulate[1...4]:LIMit[1...8]: RDOMain:FORMat This command defines the formatting of the measured value belonging to the limit line. CALCulate[1...4]:LIMit[1...
CALCulate Subsystem ZVx CALCulate[1..4]:LIMit[1...8]:CONTrol:SHIFt This command shifts a limit line along the x-axis direction by the value specified. Syntax: CALCulate<1|2>:LIMit<1...8>:CONTrol:SHIFt Example: "CALC:LIM2:CONTrol:SHIFT 50KHZ" Features: *RST value: -SCPI: device-specific The command is an "event",, which is why it is not assigned an *RST value. CALCulate[1...4]:LIMit[1...8]:CENTer This command defines the coordinates of the center of the tolerance circle. .
ZVx CALCulate Subsystem CALCulate[1...4]:LIMit[1...8]:UPPer:STATe This command switches on and off the limit check with an upper limit line. CALCulate[1...4]:LIMit[1...8]:UPPer:STATe ON | OFF Syntax: "CALC:LIM:UPPer:STAT ON" Example: Features: *RST value: SCPI: conforming The result of the limit check can be queried with the command CALCulate:LIMit<1...8>:FAIL? CALCulate[1...4]:LIMit[1...8]:UPPer:RADius This command defines the radius of the limit line in a circle diagram. CALCulate[1...4]:LIMit[1...
CALCulate Subsystem ZVx CALCulate[1...4]:LIMit[1...8]:FAIL? This command queries the result of the limit check. CALCulate[1...4]:LIMit[1...8]:FAIL? Syntax: "CALC:LIM:FAIL?" Example: Features: *RST value: SCPI: conforming CALCulate[1...4]:LIMit[1...8]:CLEar[:IMMediate] This command deletes the result of the current limit check. CALCulate[1...4]:LIMit[1...
ZVx CALCulate Subsystem 3.6.3.5 CALCulate:MARKer Subsystem The CALCulate:MARKer subsystem controls the marker functions. COMMAND PARAMETER UNIT COMMENT CALCulate<1..4> :MARKer<1...
CALCulate Subsystem ZVx CALCulate[1 to 4]:MARKer[1 to 8][:STATe] This command switches on or off the selected marker (1 to 8). If no indication is made, marker 1 is selected automatically. Syntax: CALCulate[1 to 4]:MARKer[1 to 8][:STATe] ON | OFF Example: "CALC:MARK3 ON" Features: *RST value: SCPI: OFF device-specific CALCulate[1 to 4]:MARKer[1 to 8]:AOFF This command switches off all active markers.
ZVx CALCulate Subsystem CALCulate[1 to 4]:MARKer[1 to 8]:X This command positions the selected marker to the indicated stimulus value. If the marker is a delta marker, the position can be specified either absolutely, or relative relation to the reference marker. Syntax: CALCulate[1 to 4]:MARKer[1 to 8]:X ::= 0 to MAX (frequency) | MAX (sweep time) Example: "CALC:MARK:X 10.
CALCulate Subsystem ZVx CALCulate[1...4]:MARKer[1...8]:SEARch[:IMMediate] This command triggers a search for absolute extreme values for the active marker. CALCulate[1...4]:MARKer[1...8]:SEARch[:IMMediate] Syntax: "CALC:MARK:SEAR" Example: Features: *RST value: SCPI: device-specific This command is an event,, which is why it is not assigned an *RST-value and has no query. CALCulate[1...4]:MARKer[1...8]:SEARch:NEXT This command triggers the search for the next local extreme value for the active marker.
ZVx CALCulate Subsystem CALCulate[1...4]:MARKer[1...8]:MAXimum This command triggers the search for the maximum of the trace for the active marker. CALCulate[1...4]:MARKer[1...8]:MAXimum Syntax: "CALC:MARK:MAX" Example: Features: *RST value: SCPI: – device-specific This command is an event,, which is why it is not assigned an *RST-value and has no query. CALCulate[1...4]:MARKer[1...8]:MINimum This command triggers the search for the minimum of the trace for the active marker. CALCulate[1...
CALCulate Subsystem ZVx CALCulate[1...4]:MARKer[1...8]:FUNCtion:QFACtor This command defines the quality factor for the marker search function. CALCulate[1...4]:MARKer[1...8]:FUNCtion:QFACtor Syntax: "CALC:MARK:FUNC:QFAC 100" Example: Features: *RST value: SCPI: – device-specific CALCulate[1...4]:MARKer[1...8]:FUNCtion:SFACtor This command defines the form factor for the marker search function. CALCulate[1...4]:MARKer[1...
ZVx CALCulate Subsystem CALCulate[1...4]:MARKer[1...8]:FUNCtion:EDELay:VALue? This command queries the value of the electrical or the mechanical length or the phase delay. The format of the return value must be selected beforehand with CALC:MARK:FUNC:EDEL. The suffix of MARKer has no meaning. CALCulate[1...4]:MARKer[1...8]:FUNCtion:EDELay:VALue? Syntax: "CALC:MARK:FUNC:EDEL:VAL?" Example: Features: *RST value: SCPI: -device-specific This command is a query only and therefore has no *RST value.
CALCulate Subsystem ZVx CALCulate[1...4]:MARKer[1...8]:FUNCtion:PTPeak:STATe This command switches the determination of the maximum and minimum measured value (peak-topeak value ) on or off. CALCulate[1...4]:MARKer[1...8]:FUNCtion:PTPeak:STATe ON | OFF Syntax: "CALC:MARK:FUNC:PTP:STAT ON" Example: Features: *RST value: SCPI: OFF device-specific CALCulate[1...4]:MARKer[1...8]:FUNCtion:PTPeak:RESult? This command queries the result of the peak-to-peak value search. CALCulate[1...4]:MARKer[1...
ZVx CALCulate Subsystem CALCulate[1...4]:MARKer[1...8]:FUNCtion:REFerence This command sets the reference level to the current marker level. Syntax: CALCulate[1...4]:MARKer[1...8]:FUNCtion:REFerence Example: "CALC:MARK:FUNC:REF" Features: *RST value: _ SCPI: device-specific This command is an "event",, which is why it is not assigned an *RST value and has no query. 1043.0009.50 3.
CALCulate Subsystem 3.6.3.6 ZVx CALCulate:MATH Subsystem The CALCulate:MATH - Subsystem allows to process data from the SENSe-subsystem with numerical expressions. COMMAND PARAMETER UNIT COMMENT CALCulate[1 to 4] :MATH [:EXPRession] [:DEFine] :STATe --- CALCulate[1...4]:MATH[:EXPression][:DEFine] This command defines the mathematical expression for data processing. Syntax: CALCulate[1...4]:MATH[:EXPRession][:DEFine] ::= (OP1 op OP2 [ op OP3]) OP1..OP3 ::= CH1DATA..
ZVx 3.6.3.7 CALCulate Subsystem CALCulate:SMOothing Subsystem The CALCulate:SMOothing - Subsystem allows to smooth a data set point-by-point taking into account the values at adjacent points. COMMAND PARAMETER UNIT COMMENT CALCulate<1..4> :SMOOthing [:STATe] :APERture --- CALCulate[1...4]:SMOothing[:STATe] This command determines the type of transformation of the data sets. Syntax: CALCulate[1...
CALCulate Subsystem 3.6.3.8 ZVx CALCulate:TRANsform Subsystem The CALCulate:TRANsform subsystem defines the transformation of data sets into other representations. COMMAND PARAMETER UNIT COMMENT CALCulate<1..
ZVx CALCulate Subsystem CALCulate[1...4]:TRANsform:TIME:METHod This command selects the transformation method (fast Fourier or chirp transformation) to be used. CALCulate[1...4]:TRANsform:TIME:METHod FFT | CHIRp Syntax: "CALC:TRAN:TIME:METH FFT" Example: Features: *RST-Wert: SCPI: CHIRp device-specific CALCulate[1...4]:TRANsform:TIME[:TYPE] This command selects the time domain transformation mode (lowpass or bandpass). CALCulate[1...
CALCulate Subsystem ZVx CALCulate[1...4]:TRANsform:TIME:STOP This command defines the stop time for the time domain transformation. CALCulate[1...4]:TRANsform:TIME:STOP Syntax: "CALC:TRAN:TIME:STARt 60ms" Example: Features: *RST-Wert: SCPI: + 500 ps conforming CALCulate[1...4]:TRANsform:TIME:SPAN This command defines the start time for the time domain transformation. CALCulate[1...
ZVx CALCulate Subsystem 3.6.3.9 CALCulate:UNIT Subsystem The CALCulate:UNIT - subsystem defines the physical units to be used for the measured values. COMMAND PARAMETER UNIT COMMENT CALCulate<1..4> :UNIT :POWer :A1 :A2 :B1 :B2 MW | W | UV | MV | V | DBM | DBW | DBUV | DBMV | DBV MW | W | UV | MV | V | DBM | DBW | DBUV | DBMV | DBV MW | W | UV | MV | V | DBM | DBW | DBUV | DBMV | DBV MW | W | UV | MV | V | DBM | DBW | DBUV | DBMV | DBV CALCulate[1...
DIAGnostic Subsystem 3.6.4 ZVx DIAGnostic Subsystem The DIAGnostic subsystem contains the commands which support instrument diagnostics for maintenance, service and repair. In accordance with the SCPI standard, all of these commands are device-specific. COMMAND PARAMETER DIAGnostic :SERVice :FUNCtion :RFPower ,.. UNIT COMMENT no query DIAGnostic:SERVice:FUNCtion This command activates a service function.
ZVx DISPlay Subsystem 3.6.5 DISPlay Subsystem The DISPLay subsystem controls the selection and presentation of textual and graphic information and of trace data on the display. The commands for TRACe1 refer to the active measured value memory, the commands for TRACe2 to the memory trace. COMMAND PARAMETER DISPlay :FORMat UNIT COMMENT SINGle | DOVerlay | QOVerlay | DSPLit | QDSPlit | QQSPlit :EXPand :PROgram [:MODE] :PSAVe [:STATe] :HOLDoff [:WINDow<1...
DISPlay Subsystem ZVx DISPlay:FORMat:EXPand This command switches the expanded representation on or off. DISPlay:FORMat:EXPand ON | OFF Syntax: "DISP:FORM:EXP ON" Example: Features: *RST value: SCPI: OFF device-specific DISPlay:PROGram[:MODE] This command switches the screen between the measuring instrument and the controller function.
ZVx DISPlay Subsystem DISPlay[:WINDow[1...4]]:DIAGram:SEGMented:R This command defines the segment limits for polar diagrams. A maximum of 3 segments can be defined. The separation line between two segments is common, i.e. there are neither gaps nor overlaps. The numeric values refer to the unit used in the diagram and are sorted in descending order. DISPlay[:WINDow[1...4]]:DIAGram:SEGMented:R ...
DISPlay Subsystem ZVx DISPlay[:WINDow[1 to 4]]:TRACe[1|2]:Y[:SCALe]:RLEVel This command defines the reference level.
ZVx DISPlay Subsystem DISPlay[:WINDow[1 to 4]]:TRACe[1|2]:Y[:SCALe]:BOTTom This command defines the lower edge of the grid.
DISPlay Subsystem ZVx DISPlay[:WINDow[1 to 4]]:TRACe[1|2]:Y[:SCALe]:OFFSet This command defines an offset value to be added to the output values.
ZVx DISPlay Subsystem DISPlay[:WINDow[1 to 4]:TRACe[1|2][:STATe] This command switches the display of the current trace on or off. Syntax: DISPlay[:WINDow[1 to 4]]:TRACe[1|2][:STATe] ON | OFF Example: "DISP:TRAC2 ON" Features: *RST value: SCPI: 1043.0009.50 ON for TRACe1, OFF for TRACe2 conforming 3.
FORMat Subsystem 3.6.6 ZVx FORMat Subsystem The FORMat subsystem specifies the format of the data transmitted from and to the analyzer. COMMAND FORMat [:DATA] :DEXPort :FORMat :MODe :DSEParator :SOURce PARAMETER UNIT COMMENT ASCii|REAL[,] ASCii | TOUChstone | SCOMpact COMPlex | MLPHase | MDPHase NEW | APPend POINt | COMMa CDATa | CVData | TDATa | FDATa | MDATa | DDATa FORMat[:DATA] This command defines the data format for transmission from and to the analyzer.
ZVx FORMat Subsystem FORMat:DEXPort This command defines the format of the file to be generated. FORMat:DEXPort ASCii | TOUChstone | SCOMpact Syntax: "FORM:DEXP ASCII" Example: *RST value: ASCii SCPI: conforming The file format can be compatible to ASCII (can be imported into arbitrary applications), TOUCHSTONE or SUPERCOMPACT Features: FORMat:DEXPort:FORMat This command defines the format for representing the measurement values.
FORMat Subsystem ZVx FORMat:DEXPort:SOURce This command defines the source of measurement data. FORMat:DEXPort:SOURce CDATa | CVData | TDATa | FDATa | MDATa | Syntax: DDATa "FORM:DEXP:SOUR CDAT" Example: Features: *RST value: SCPI: DDATa conforming The possible sources correspond to different stages in the flow of measurement data: Receiver power correction Recording of meas.
ZVx 3.6.7 HCOPy Subsystem HCOPy Subsystem The HCOPy subsystem controls the output of screen information to output devices or files for documentation purposes. COMMAND HCOPy :ABORt :DESTination<1|2> :DEVice :COLor :LANGuage<1|2> :PRESet<1|2> :RESolution<1|2> [:IMMediate<1|2>] :ITEM :ALL :FFEed<1|2> :STATe :LABEL :TEXT :PFEed<1|2> :STATe :WINDow<1...4> :TABLe :STATe :TEXT :TRACe<1|2> :STATe :CAINcrement :LTYPe :STATe :AINCrement :PAGE :DIMensions :QUADrant<1...4> :FULL :ORIentation<1|2> 1043.0009.
HCOPy Subsystem ZVx HCOPy:ABORt This command aborts an active print job. Syntax: HCOPy:ABORt Example: "HCOP:ABOR" Features: *RST value: – SCPI: conforming This command is an "event", which is why it is not assigned an *RST value and has no query. HCOPy:DESTination<1|2> This command selects the device for outputting the hardcopy.
ZVx HCOPy Subsystem HCOPy:DEVice:LANGuage<1|2> This command determines the data format of the printout.
HCOPy Subsystem ZVx HCOPy:ITEM:ALL This command selects the complete screen to be output. Syntax: HCOPy:ITEM:ALL Example: "HCOP:ITEM:ALL" Features: *RST value: OFF SCPI: conforming The hardcopy output is always provided with comments, title, time and date. As an alternative to the whole screen, only traces (commands ’HCOPy:DEVice:WINDow:TRACe:STATe ON’) or tables (command ’HCOPy:DEVice:WINDow:TABLe:STATe ON’) can be output.
ZVx HCOPy Subsystem HCOPy:ITEM:WINDow<1...4>:TEXT This command selects the comment text for printout to trace 1 or 2. Syntax: HCOPy:ITEM:WINDow<1...4>:TEXT Example: "HCOP:ITEM:WIND2:TEXT ‘Comment’" Features: *RST value: SCPI: – device-specific HCOPy:ITEM:WINDow<1...4>:TRACe:STATe This command selects the currently displayed trace for output. Syntax: HCOPy:ITEM:WINDow<1...
HCOPy Subsystem ZVx HCOPy:ITEM:WINDow[1...4]:TRACe[1|2]:LTYPe:AINCrement This command causes automatic incrementation of the line style of the active-channel test trace after each hardcopy generated. The command is available only if a plotter is selected as an output device. The command has no effect on the memory traces. In automatic incrementation, line styles STYLe7 to STYLe3 are activated one after the other. Syntax: HCOPy:ITEM:WINDow[1...
ZVx 3.6.8 INITiate Subsystem INITiate Subsystem The INITiate subsystem controls the initialization of the trigger subsystem. COMMAND PARAMETER INITiate :CONTinuous [:IMMediate] -- UNIT --- COMMENT no query INITiate:CONTinuous This command determines if the trigger system is continuously initiated ("Free Run")..
INPut Subsystem 3.6.9 ZVx INPut Subsystem The INPut subsystem controls the features of the input of the instrument. COMMAND PARAMETER INPut :ATTenuation :BRIDge :UPORt<1|2> [:VALue?] :STATe INTernal | BYPass | FPORt UNIT COMMENT DB - INPut[1|2]:ATTenuation This command determines the attenuation of the attenuator in the signal path of the incident wave b1 or b2. INPut[1|2]:ATTenuation Syntax: Example: Features: ::= 0dB..
ZVx 3.6.10 INSTrument Subsystem INSTrument Subsystem The INSTrument subsystem selects the measuring mode of the instrument either via text parameters or via assigned default numbers. COMMAND PARAMETER INSTrument :COUPle [:SELect] UNIT COMMENT ALL | NONE CHANNEL1 | CHANNEL2 | CHANNEL3 | CHANNEL4 :NSELect INSTrument:COUPle This command switches the coupling of the display channels of the analyzer on or off.
MMEMory Subsystem 3.6.11 ZVx MMEMory Subsystem The MMEMory (mass memory) subsystem provides the commands which allow for access to the storage media of the instrument and for storing and loading various instrument settings. The NAMe command stores the HCOPy outputs in a file. The various drives can be addressed via the mass storage unit specifier using the conventional DOS syntax. The internal hard disk is addressed by "C:", the floppy-disk drive installed by "A:".
ZVx MMEMory Subsystem COMMAND PARAMETER :SELect [:ITEM] :GSETup :HWSettings :LINes [:ALL] :CSETup :CDATa :CKData :HCOPy :MACRos :MTRace<1...8> :AFILes :ALL :NONE :DEFault :COMMent UNIT COMMENT --- no query no query no query MMEMory:CATalog? This command queries the contents of the current directory.
MMEMory Subsystem ZVx MMEMory:DATA This command writes block data to a specified file. MMEMory:DATA , Syntax: MMEMory:DATA? ::= DOS file name ::= binary data block "MMEM:DATA? ’TEST01.HCP’" Example: Features: *RST value: SCPI: – conforming The delimiter must be set to EOI in order to obtain a perfect data transfer. MMEMory:DELete This command deletes the files indicated.
ZVx MMEMory Subsystem MMEMory:LOAD:STATe This command loads instrument settings from files. Syntax: MMEMory:LOAD:STATe 1, ::= DOS file name Example: "MMEM:LOAD:STAT 1,’A:TEST.CFG’" Features: *RST value: SCPI: – conforming The contents of the file are loaded and determine the new state of the instrument. The file name may comprise the specification of the path and, eventually, the name of the drive. Indication of the path is according to the DOS conventions.
MMEMory Subsystem ZVx MMEMory:NAME This command specifies a file which is printed or plotted. Syntax: MMEMory:NAME ::= DOS filename Example: "MMEM:NAME ’PLOT1.HPG’" Features: *RST value: SCPI: conforming The file name may comprise the specification of the path and, eventually, the name of the drive. Indication of the path is according to the DOS conventions. The output to the printer is routed into a file using the command "HCOP:DEST ’MMEM’".
ZVx MMEMory Subsystem MMEMory:CLEar:ALL This command deletes all device settings in the current directory. Syntax: MMEMory:CLEar:ALL Example: "MMEM:CLE:ALL" Features: *RST value: SCPI: device-specific This command is an "event", which is why it is not assigned an *RST-value and has no query. MMEMory:SELect[:ITEM]:GSETup This command includes the general setup data in the list of partial data sets of a device setting which are to be stored/loaded.
MMEMory Subsystem ZVx MMEMory:SELect[:ITEM]:CSETup This command includes the current screen color settings in the list of partial data sets of a device setting which are to be stored/loaded. Syntax: MMEMory:SELect[:ITEM]:CSETup ON|OFF Example: "MMEM:SEL:CSET ON" Features: *RST value: ON SCPI: device-specific MMEMory:SELect[:ITEM]:CDATa This command includes the current calibration data in the list of partial data sets of a device setting which are to be stored/loaded.
ZVx MMEMory Subsystem MMEMory:SELect[:ITEM]:AFILes This command includes the ASCII data sets generated in the list of partial data sets of a device setting which are to be stored/loaded. Syntax: MMEMory:SELect[:ITEM]:AFILes ON|OFF Example: "MMEM:SEL:AFILes ON" Features: *RST value: OFF SCPI: device-specific MMEMory:SELect[:ITEM]:ALL This command includes all partial data sets in the list of partial data sets of a device setting which are to be stored/loaded.
OUTPut Subsystem 3.6.12 ZVx OUTPut Subsystem The OUTPut subsystem controls the output features of the analyzer. COMMAND PARAMETER OUTPut<1|2> :ATTenuation :DPORt :POWer :RMIXer [:STATe] :UPORt<1|2> [:VALue] :STATe PORT1 | PORT2 NORMal | HIGH UNIT COMMENT DB OUTPut[1|2]:ATTenuation This command determines the attenuation of the attenuator located in the signal path of the wave a1 or a2 propagating towards the DUT.
ZVx OUTPut Subsystem OUTPut:UPORt<1|2>[:VALue] This command sets the control lines of the user port. If the user port was set to INPut previously, the output value is stored intermediately. Syntax: OUTPut:UPORt<1|2>[:VALue] ::= 00000000 ... 11111111 Example: "OUTP:UPOR2 #B10100101" Features: *RST value: SCPI: – device-specific OUTPut:UPORt<1|2>:STATe This command toggles the control lines of the user ports between INPut and OUTPut.
PROGram - Subsystem 3.6.13 ZVx PROGram - Subsystem The PROGram-subsystem contains commands used to start and control application programs on the instrument. COMMAND PARAMETER PROGram [:SELected] :NAME :STRing :EXECute UNIT ZVR_K9 | PROG [,] COMMENT no query PROGram[:SELected]:NAME This command specifies the name of the application to be selected.
ZVx PROGram - Subsystem PROGram[:SELected]:EXECute This command executes the specified command in the selected application. PROGram[:SELected]:EXECute Syntax: ::= Example: Features: ’EMBED’ | ’DEEMBED’ | ’RUN’ "PROG:EXEC ’EMBED’" *RST value: SCPI: conforming The commands ’EMBED’ and ’DEEMBED’ enable the calculation of input files (previously indicated by PROG:STR) in the ZVR_K9 application. The ’RUN’ command starts an application at the operation system level. 1043.0009.50 3.
SENSe Subsystem 3.6.14 ZVx SENSe Subsystem The SENSe subsystem is divided up into several subsystems. The commands of these subsystems directly control device-specific settings, they do not refer to the signal characteristics of the measurement signal. 3.6.14.1 SENSe:AVERage Subsystem The SENSe:AVERage subsystem calculates the average of the data acquired: Various successive measurements are combined in order to obtain a new test result.
ZVx SENSe Subsystem [:SENSe[1 to 4]:]AVERage:MODE The command selects the type of the average function. Syntax: [:SENSe[1 to 4]:]AVERage:MODE SWEep | POINt Example: "AVER:MODE POIN" Features: *RST value: SCPI: 3.6.14.2 NORMal device-specific SENSe:BANDwidth Subsystem This subsystem controls the setting of the analyzer’s filter bandwidths. The commands BANDwidth and BWIDth have the same effect. COMMAND [SENSe<1...
SENSe Subsystem 3.6.14.3 ZVx SENSe:CORRection Subsystem The SENSe:CORRection subsystem controls the system error correction and the recording of the individual correction values. COMMAND PARAMETER [SENSe<1...4>] :CORRection [:STATe] :DATA :DATE? :INTerpolate [:STATe] :AKAL :SELect :EXPort :IMPort :CLEar :REName :COLLect [:ACQuire] :METHod :SAVE :CONNection<1|2> :CKIT :INSTall :N<50|75> :SELect 1043.0009.50 UNIT COMMENT , | ...
ZVx SENSe Subsystem COMMAND [SENSe<1...
SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :N<50|75> :MFSNetwork :FFSNetwork :MOPen :FOPen :MSHort :FSHort 1043.0009.
ZVx SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :N<50|75> :MREFlect :FREFlect :MMTCh :FMTCh :MSMatch :FSMatch 1043.0009.
SENSe Subsystem COMMAND ZVx PARAMETER [SENSe<1...4>] :CORRection :CKIT :SMA :SELect :MMTHrough :MFTHrough :FFTHrough :MMLINE<1|2> :MFLINE<1|2> :FFLINE<1|2> :MMATten :MFATten :FFATten 1043.0009.
ZVx SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :SMA :MMSNetwork :MFSNetwork :FFSNetwork :MOPen :FOPen :MSHort 1043.0009.
SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :SMA :FSHort :MREFlect :FREFlect :MMTCh :FMTCh :MSMatch :FSMatch 1043.0009.
ZVx SENSe Subsystem COMMAND PARAMETER [SENSe<1...4>] :CORRection :CKIT :PC<7|35|292> :SELect :MMTHrough :MFTHrough :FFTHrough :MMLINE<1|2> :MFLINE<1|2> :FFLINE<1|2> :MMATten :MFATten :FFATten 1043.0009.
SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :PC<7|35|292> :MMSNetwork :MFSNetwork :FFSNetwork :MOPen :FOPen :MSHort 1043.0009.
ZVx SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :PC<7|35|292> :FSHort :MREFlect :FREFlect :MMTCh :FMTCh :MSMatch :FSMatch 1043.0009.
SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :USER<1|2> :SELect :IMPedance :WGUide [:STATe] :CFRequency :MMTHrough :MFTHrough :FFTHrough :MMLINE<1|2> :MFLINE<1|2> :FFLINE<1|2> :MMATten :MFATten :FFATten 1043.0009.
ZVx SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :USER<1|2> :MMSNetwork :MFSNetwork :FFSNetwork :MOPen :FOPen :MSHort 1043.0009.
SENSe Subsystem COMMAND [SENSe<1...4>] :CORRection :CKIT :USER<1|2> :FSHort :MREFlect :FREFlect :MMTCh :FMTCh :MSMatch :FSMatch 1043.0009.
ZVx COMMAND [SENSe<1...4>] :CORRection :EDELay<1|2> [:TIME] :DISTance :ELENgth :DIELectric :AUTO :STATe :OFFSet<1|2> :STATe :MAGNitude :PHASe :POWer [:STATe] :DATE? :ACQuire SENSe Subsystem PARAMETER UNIT ONCE s m m COMMENT no query DB DEG only query no query B1 | B2 | IFRef [SENSe[1...4]:]CORRection:AKAL:SELect This command selects an active data set for the AutoKal box.
SENSe Subsystem ZVx [SENSe[1...4]:]CORRection:AKAL:CLEar This command clears the selected data set for the AutoKal box. The suffix of SENSe is not significant. [SENSe[1...4]:]CORREction:AKAL:CLEar Syntax: "CORR:AKAL:CLE ‘AK1’" Example: Features: *RST value: SCPI: device-specific The command is an "event",, which is why it is not assigned an *RST value and has no query. [SENSe[1...
ZVx SENSe Subsystem [SENSe[1...4]:]CORRection:COLLect:METHod This command defines the calibration method. [SENSe[1...4]:]CORRection:COLLect:METHod Syntax: Example: "CORR:COLL:METH TOM" Features: *RST value: SCPI: FTRans | RTRans | FRTRans | TOM | TRM | TRL | TNA | TOMX| TOSM | FUNDamental | FOPORT1 | FOPORT2 | FOPORT12 | FOPTport | ROPTport | REFL1 | REFL2 | REFL12 | TPORT | FTREF1 | RTREF2 – conforming [SENSe[1...
SENSe Subsystem ZVx [SENSe[1...4]:]CORRection:CKIT:INSTall The command installs a calibration kit data set from a file. [SENSe[1...4]:]CORREction:CKIT:INSTall Syntax: "CORR:CKIT:INST ‘A:\mykit.ck’" Example: Features: *RST value: SCPI: device-specific [SENSe[1...4]:]CORRection:CKIT:: The command configures the parameters of the different standards. [SENSe[1...
ZVx SENSe Subsystem [SENSe[1...4]:]CORRection:CKIT::SELect This command selects a defined calibration kit from the specified connector family. [SENSe[1...4]:]CORREction:CKIT::SELect Syntax: "CORR:CKIT:N50:SEL ‘ZCAN’ Example: Features: *RST value: SCPI: device-specific [SENSe[1...4]:]CORRection:CKIT:USER<1|2>:IMPedance This command sets the impedance of the USER calibration kit. [SENSe[1...
SENSe Subsystem ZVx Two-port standards are either MM = connector/connector, FF = socket/socket or MF = connector/socket, one-port standards are either M = connector or F = socket.
ZVx SENSe Subsystem [SENSe[1...4]:]CORRection:EDELay[1|2]:ELENgth This command defines the length offset as an electrical length. [SENSe[1...4]:]CORRection:EDELay[1|2]:ELENgth Syntax: "CORR:EDEL:ELEN 12.32mm" Example: Features: *RST value: SCPI: 0 device-specific [SENSe[1...4]:]CORRection:EDELay[1|2]:DIELectric This command defines the value of the dielectric corresponding to the length specified via EDELay:DISTance. [SENSe[1...
SENSe Subsystem ZVx [SENSe[1...4]:]CORRection:OFFSet[1|2]:MAGNitude This command defines the amplitude offset. [SENSe[1...4]:]CORRection:OFFSet[1|2]:MAGNitude Syntax: "CORR:OFFS:MAGN 3" Example: Features: *RST value: SCPI: 0 conforming [SENSe[1...4]:]CORRection:OFFSet[1|2]:PHASe This command defines the phase offset. [SENSe[1...4]:]CORRection:OFFSet[1|2]:PHASe Syntax: "CORR:OFFS:PHAS 23" Example: Features: *RST value: SCPI: 0 conforming [SENSe[1...
ZVx SENSe Subsystem The table below shows the correction terms available for the calibration methods: Calibration Method Available Correction Terms Trans Norm Forward Trans Norm Reverse SCORR6 SCORR12 Trans Norm both Directions SCORR6, SCORR12 Refl Norm P1 Refl Norm P2 SCORR3 SCORR9 Refl Norm both Ports SCORR3, SCORR9 Trans+Refl Norm Forward Trans+Refl Norm Reverse SCORR3, SCORR6 SCORR9, SCORR12 Trans+Refl Norm both Ports SCORR3, SCORR6, SCORR9, SCORR12 Full One Port P1 Full One Port P2 SCO
SENSe Subsystem ZVx [SENSe[1...4]:]CORRection:POWer:DATA This command is used for reading and writing power correction values for a receiver channel.
ZVx 3.6.14.4 SENSe Subsystem SENSe:DETector Subsystem Das SENSe:DETector-subsystem controls how the analyzer takes measurement data. COMMAND [SENSe<1..4>] :DETector [:FUNCtion] PARAMETER UNIT COMMENT FAST | NORMal [SENSe[1...4]:]DETector[:FUNCtion] This command switches the fast measurement mode on and off. [SENSe[1...4]:]DETector[:FUNCtion] Syntax: "DET FAST" Example: Features: 1043.0009.50 *RST value: SCPI: NORMal device-specific 3.
SENSe Subsystem 3.6.14.5 ZVx SENSe:FREQuency Subsystem The SENSe:FREQuency subsystem controls the frequency abscissa of the active display. The frequency abscissa can either be defined via the start/stop frequency or via the center frequency and span. The following frequency ranges apply to the different instrument models.
ZVx SENSe Subsystem [SENSe[1 to 4]:]FREQuency:CENTer This command defines the center frequency of the analyzer. Syntax: [SENSe[1 to 4]:]FREQuency:CENTer ::= model-dependent range (see table at the beginning of this subsystem) Example: "FREQ:CENT 100MHz" Features: *RST value: SCPI: – conforming [SENSe:]FREQuency:SPAN This command defines the frequency span of the analyzer.
SENSe Subsystem ZVx [SENSe[1...4]:]FREQuency:MODE This command determines which command groups are used for setting the frequency of the analyzer. Syntax: [SENSe[1...4]:]FREQuency:MODE CW | FIXed | SWEep | SEGMent Example: "FREQ:MODE SWE" Features: *RST value: SWE SCPI: conforming For CW and FIXed, the frequency setting is via command FREQuency:CW. In the SWEep mode, the setting is via the commands FREQuency:STARt, STOP, CENTer and SPAN.
ZVx SENSe Subsystem [SENSe[1...4]:]FREQuency:CONVersion:MIXer:FUNDamental For mixer measurements, this command selects the fundamental frequency out of the three mixer frequencies. . [SENSe[1...4]:]FREQuency:CONVersion:MIXer:FUNDamental RF | LO | IF Syntax: "FREQ:CONV:MIX:FUND RF" Example: Features: *RST value: SCPI: LO device-specific [SENSe[1...4]:]FREQuency:CONVersion:MIXer:LOEXternal This command selects one of the two external signal sources as a local oscillator. [SENSe[1...
SENSe Subsystem ZVx [SENSe[1...4]:]FREQuency:CONVersion:MIXer:TFRequency. This command determines the sign of the third mixer frequency by selecting either the lower or upper band. [SENSe[1...4]:]FREQuency:CONVersion:MIXer:TFRequency BAND1 | Syntax: BAND2 "FREQ:CONV:MIX:TFR BAND2" Example: Features: *RST value: SCPI: BAND1 device-specific [SENSe[1...
ZVx 3.6.14.6 SENSe Subsystem SENSe:FUNCtion Subsystem The SENSe:FUNCtion-Subsystem defines the measurement function performed by the analyzer. COMMAND [SENSe<1..4>] :FUNCtion [:ON] PARAMETER UNIT COMMENT [SENSe[1...4]:]FUNCtion[:ON] This command defines the measurement function performed by the analyzer in one string. [SENSe[1...4]:]FUNCtion[:ON] Syntax: ::= "XFRequency:POWer:A<1|2>" "XFRequency:POWer:B<1|2>" "XFRequency:POWer:S<11..22>" "XFRequency:POWer:S<11..
SENSe Subsystem ZVx "XFRequency:NLINear:TOI:CHECk:LEVel ON | OFF" "XFRequency:NLINear:TOI:CHECk:IPNoise ON | OFF" "XFRequency:NLINear:TOI:CHECk:CUBic ON | OFF" "XFRequency:NLINear:TOI:CHECk:RIMod ON | OFF" "XFRequency:NLINear:TOI:CHECk:COMP ON | OFF" "XFRequency:NLINear:TOI:CHECk:ESRC ON | OFF" "XPOWer:POWer:A<1|2>" "XPOWer:POWer:B<1|2>" "XPOWer:POWer:S<11..22>" "XPOWer:POWer:S<11..22>:DEFine B1 | B2 | A1, A1 | B1 | B2" "XPOWer:POWer:Z<11..22>" "XPOWer:POWer:Y<11..22>" "XPOWer:POWer:ZREL<11..
ZVx 3.6.14.7 SENSe Subsystem SENSe:ROSCillator - Subsystem Dieses Subsystem controls the reference oscillator. COMMAND [SENSe] :ROSCillator [:SOURce] :EXTernal FREQuency PARAMETER UNIT INTernal | EXTernal -- HZ COMMENT [SENSe:]ROSCillator[:SOURce] This command selects the reference oscillator..
SENSe Subsystem 3.6.14.8 ZVx SENSe:SEGMent Subsystem The SENSe:SEGMent-Subsystem defines the parameter for a segmented sweep. COMMAND PARAMETER [SENSe<1..4>] :SEGMent :DEFine<1...50> :CLEar :INSert<1...
ZVx SENSe Subsystem [SENSe[1...4]:]SEGMent:CLEar This command deletes all segments [SENSe[1...4]:]SEGMent:CLEar Syntax: "SEG:CLE" Example: Features: *RST value: SCPI: device-specific This command is an event, which is why it is not assigned an *RST value and has no query. [SENSe[1...4]:]SEGMent:INSert[1...50] This command inserts a segment into an existing list. [SENSe[1...4]:]SEGMent:INSert[1...
SENSe Subsystem 3.6.14.9 ZVx SENSe:SWEep Subsystem This subsystem controls the sweep parameters. COMMAND PARAMETER [SENSe<1..4>] :SWEep :TIME :AUTO :COUNt :POINts :SPACing :STEP :PDECade :DIRection LINear | LOGarithmic UP | DOWN UNIT COMMENT S ----HZ -- [SENSe[1 to 4]:]SWEep:TIME This command defines the duration of the sweep.
ZVx SENSe Subsystem [SENSe[1 to 4]:]SWEep:POINts This command defines the number of measured points in one sweep. Syntax: Example: Features: [SENSe[1 to 4]:]SWEep:POINts ::= 1... 2001 "SWE:POIN 10" *RST value: SCPI: 400 conforming [SENSe[1 to 4]:]SWEep:SPACing This command switches over between linear and logarithmic sweep.
SOURce Subsystem 3.6.15 ZVx SOURce Subsystem The SOURce subsystem directly controls device-specific settings which are necessary for signal generation.
ZVx SOURce Subsystem COMMAND PARAMETER SOURce<1...4> :POWer :CENTer :SPAN :STARt :STOP :CORRection :DATA COMMENT dBm dB dBm dBm , | ...
SOURce Subsystem ZVx SOURce<1...4>:POWer[:LEVel][:IMMediate]:CAMPlitude:A<1|2> This command defines the level of the output signal a1 / a2 when the power correction is switched on or when a power calibration is started. SOURce<1...4>:POWer[:LEVel][:IMMediate]: Syntax: CAMPlitude:A<1|2> ::= -300dBm...+200dBm "SOUR:POW:CAMP:A1 -10dBm" Example: Features: *RST value: SCPI: 0 dBm conforming SOURce<1...
ZVx SOURce Subsystem SOURce[1...4]: POWer:ALC[:STATe] This command is for controlling the ALC loop of the analyzer. With ON the internal ALC loop is closed, with OFF an external control signal fed via a rear-panel connector is used. The channel specification (1 to 4) is of no importance here since this is a global setting. Syntax: SOURce[1...4]: POWer:ALC[:STATe] Example: "SOUR:POW:ALC ON" Characteristics: *RST value: SCPI: ON | OFF ON conforming SOURce[1...
SOURce Subsystem ZVx SOURce[1...4]:POWer:NLINear:SOI:RANGe:LOWer nd This command defines a lower limit for the power of the signal sources for a 2 order intercept point measurement. The allowed range of lower limits depends on the power of the signal sources. With power calibration, the lower limit must be set such that it can be reached by both signal sources. SOURce[1...
ZVx SOURce Subsystem SOURce<1...4>: POWer:SPAN This command defines the level display range of the analyzer in the level sweep mode. SOURce<1...4>: POWer:SPAN Syntax: Example: Features: ::= 0dBm to 25 dB (device-specific) "SOUR:POW:SPAN 10dB" *RST value: SCPI: MAXimum conforming SOURce<1...4>: POWer:STARt This command defines the start level in the level sweep mode. SOURce<1...
SOURce Subsystem ZVx SOURce<1...4>: POWer:CORRection:EXT<1|2>:SWEep This command defines the sweep parameters to be used when an external generator power calibration is started. SOURce<1...4>:POWer: , Syntax: CORRection:EXT<1|2>:SWEep ,, LIN | LOG "SOUR:POW:CORR:EXT1:SWE 10MHZ,1GHZ,101,LOG" Example: Features: *RST value: SCPI: .., ..
ZVx SOURce Subsystem SOURce<1...4>: POWer:CORRection:LLISt:STATe This command defines whether the power loss list should be used for a power calibration. SOURce<1...4>:POWer:CORRection:LLISt:STATe ON | OFF Syntax: "SOUR:POW:CORR:LLIS:STAT ON" Example: Features: *RST value: SCPI: OFF conforming SOURce<1...4>:FREQuency[:CW|FIXed] This command defines the CW-frequency for the POWER SWEEP and TIME SWEEP modes. SOURce<1...
SOURce Subsystem ZVx SOURce[1...4]:FREQuency:NLINear:COMP This command specifies whether the internal signal source or one of the two external sources is to be used for the compression point measurement. SOURce[1...4]:FREQuency:NLINear:COMP INT | ESRC1 | ESRC2 Syntax: "SOUR:FREQ:NLIN:COMP INT" Example: Features: *RST value: SCPI: INT device-specific SOURce[1...
ZVx 3.6.16 STATus Subsystem STATus Subsystem The STATus subsystem contains the commands for the status-reporting system (see Section 3.8, Status Reporting System"). *RST does not influence the status registers.
STATus Subsystem ZVx STATus:OPERation:CONDition? This command queries the CONDition section of the STATus:OPERation register. Syntax: STATus:OPERation:CONDition? Example: "STAT:OPER:COND?" Features: *RST value: SCPI: – conforming Readout does not delete the contents of the CONDition section. The value returned reflects the current hardware status. STATus:OPERation:ENABle This command sets the bits of the ENABle section of the STATus:QUEStionable register.
ZVx STATus Subsystem STATus:QUEStionable[:EVENt?] This command queries the contents of the EVENt section of the STATus:QUEStionable register. Syntax: STATus:QUEStionable[:EVENt?] Example: "STAT:QUES?" Features: *RST value: – SCPI: conforming Readout deletes the contents of the EVENt section. STATus:QUEStionable:CONDition? This command queries the CONDition section of the STATus:QUEStionable register.
STATus Subsystem ZVx STATus:QUEStionable:FREQuency[:EVENt?] This command queries the contents of the EVENt section of the STATus:QUEStionable:FREQuency register. STATus:QUEStionable:FREQuency[:EVENt?] Syntax: "STAT:QUES:FREQ?" Example: Characteristics: *RST value: SCPI: device-specific The contents of the EVENt section are cleared on reading out. STATus:QUEStionable:FREQuency:CONDition? This command queries the CONDition section of the STATus:QUEStionable:FREQuency register.
ZVx STATus Subsystem STATus:QUEStionable:LIMit[:EVENt?] This command queries the contents of the EVENt-section of the STATus:QUEStionable:LIMitregister. STATus:QUEStionable:LIMit[:EVENt?] Syntax: "STAT:QUES:LIM?" Example: Features: *RST value: SCPI: – device-specific Readout deletes the contents of the EVENt section. STATus:QUEStionable:LIMit:CONDition? This command queries the CONDition-section of the STATus:QUEStionable:LIMit-register.
STATus Subsystem ZVx STATus:QUEStionable:POWer[:EVENt?] This command queries the contents of the EVENt section of the STATus:QUEStionable:POWerregister. STATus:QUEStionable:POWer[:EVENt?] Syntax: "STAT:QUES:POW?" Example: Characteristics: *RST value: SCPI: – device-specific The contents of the EVENt section are cleared on reading out. STATus:QUEStionable:POWer:CONDition? This command queries the CONDition section of the STATus:QUEStionable:POWer register.
ZVx STATus Subsystem STATus:QUEue[:NEXT?] This command queries the earliest entry to the error queue, thus deleting it. Syntax: STATus:QUEue[:NEXT?] Example: "STAT:QUE?" Features: *RST value: – SCPI: conforming Positive error numbers indicate device-specific errors, negative error numbers are error messages defined by SCPI (cf. Appendix B). If the error queue is empty, the error number 0, "no error", is returned. This command is identical with the command SYSTem:ERRor. 1043.0009.50 3.
SYSTem Subsystem 3.6.17 ZVx SYSTem Subsystem The SYSTem subsystem lists commands for general functions.
ZVx COMMAND :PRESet :SET :TIME :VERSion? SYSTem Subsystem PARAMETER UNIT - 0...23, 0...59, 0...59 -- COMMENT query only SYSTem:COMMunicate:AKAL[:STATe] This command switches the control of the AutoKal box on and off. SYSTem:COMMunicate:AKAL[:STATe] Syntax: "SYST:COMM:AKAL ON" Example: Features: *RST value: SCPI: ON | OFF – (no influence on this parameter) device-specific SYSTem:COMMunicate:GPIB[:SELF]:ADDRess This command changes the IEC/IEEE-bus address of the unit.
SYSTem Subsystem ZVx SYSTem:COMMunicate:GPIB:RDEVice:GENerator<1|2>:ADDRess This command changes the IEC-bus address of the device selected as generator no. 1 or 2. SYSTem:COMMunicate:GPIB:RDEVice:GENerator<1|2>: ADDRess 0...30 Syntax: "SYST:COMM:GPIB:RDEV:GENerator1:ADDR 19" Example: Features: *RST value: SCPI: device-specific SYSTem:COMMunicate:GPIB:RDEVice:PMETer:ADDRess This command changes the IEC-bus address of the device selected as power meter.
ZVx SYSTem Subsystem SYSTem:COMMunicate:PRINter<1|2>:SELect This command selects one of the printers installed under Windows NT. The numeric suffix in PRINter<1|2> selects the device. The name of the first printer is queried with FIRSt?. After that the names of other installed printers can be queried with NEXT?. Parameter: ::= string which has been queried with commands SYSTem:COMMunicate:PRINter:ENUMerate:FIRSt? and NEXT?.
SYSTem Subsystem ZVx SYSTem:COMMunicate:RDEVice:GENerator<1|2>:TYPE This command selects the type of external generator.
ZVx SYSTem Subsystem SYSTem:COMMunicate:RDEVice:PMETer:CFACtor:ASENsor This command defines the sensor factor list for sensor A which can be active for a power calibration. SYSTem:COMMunicate: ,, Syntax: RDEVice:PMETer:CFACtor:ASENsor ... "SYST:COMM:RDEV:PMET:CFAC:ASEN 2,10HZ,99PCT,4GHZ,98PCT" Example: Features: *RST value: SCPI: 0 (i.e.
SYSTem Subsystem ZVx SYSTem:COMMunicate:SERial<1|2>:CONTrol:DTR SYSTem:COMMunicate:SERial<1|2>:CONTrol:RTS These commands switch the hardware handshake procedure for the given serial interface off (OFF) or on (IBFull). Syntax: SYSTem:COMMunicate:SERial<1|2>:CONTrol:DTR IBFull | OFF SYSTem:COMMunicate:SERial<1|2>:CONTrol:RTS IBFull | OFF Examples: "SYST:COMM:SER:CONT:DTR OFF" "SYST:COMM:SER2:CONT:RTS IBF" Features: *RST value: OFF SCPI: conforming The two commands have the same meaning.
ZVx SYSTem Subsystem SYSTem:COMMunicate:SERial<1|2>[:RECeive]:SBITs This command defines the number of stopbits per data word for the given serial interface. Syntax: SYSTem:COMMunicate:SERial<1|2>[:RECeive]:SBITs 1|2 Example: "SYST:COMM:SER:SBITs 2" Features: *RST value: 1 SCPI: conforming SERial1 and SERial 2 correspond to device interface COM1 and COM2, respectively. SYSTem:COMMunicate:SERial<1|2>[:RECeive]:PACE This command switches on or off the software handshake for the given serial interface.
SYSTem Subsystem ZVx SYSTem:ERRor[:NEXT]? This command queries and at the same time deletes the oldest entry in the error queue. Syntax: SYSTem:ERRor? Example: "SYST:ERR?" Features: *RST value: SCPI: – conforming Positive error numbers indicate device-specific errors, negative error numbers are error messages defined by SCPI (cf. Appendix B). If the error queue is empty, the error number 0, "no error", is returned. This command is identical with the command STATus:QUEue:NEXT?.
ZVx SYSTem Subsystem SYSTem:PRESet This command triggers an instrument reset. Syntax: SYSTem:PRESet Example: "SYST:PRES" Features: *RST value: – SCPI: conforming The effect of this command corresponds to that of the PRESET key for manual control or to the *RST command. SYSTem:SET This command loads the instrument setting previously stored via SYSTem:SET?.
TRACe Subsystem 3.6.18 ZVx TRACe Subsystem The TRACe subsystem controls access to the instrument’s internal trace memory. COMMAND TRACe :COPY :CLEar [:DATA] [:RESPonse] [:ALL]? :PREamble? :BODY? :STIMulus [:ALL]? :PREamble? :BODY? :FEED 1043.0009.
ZVx TRACe Subsystem TRACe:COPY This command copies the trace data of the active channel to one of the 8 memory traces. Syntax: TRACe:COPY , ::= MDATA1 | MDATA2 | MDATA3 | MDATA4 | MDATA5 | MDATA6 | MDATA7 | MDATA8 ::= CH1DATA | CH2DATA | CH3DATA | CH4DATA Examples: "TRAC:COPY MDATA5,CH1DATA" Features: *RST value: SCPI: conforming TRACe:CLEar This command clears the corresponding memory trace.
TRACe Subsystem ZVx TRACe[:DATA][:RESPonse]:BODY? This query command reads the response values of the trace data from the device. With binary data transmission, these are only the useful data without the SCPI block data header.
ZVx TRACe Subsystem TRACe:FEED This command transfers data from the internal memory traces to the channel specific memories for measured values. TRACe:FEED CH1MEM | CH2MEM | CH3MEM | CH4MEM Syntax: [, MDATA1 | MDATA2 | MDATA3 | MDATA4 | MDATA5 | MDATA6 | MDATA7 | MDATA8] "TRAC:COPY CH1MEM,MDAT5" Example: Features: 1043.0009.50 *RST value: SCPI: – conforming 3.
TRIGger-Subsystem 3.6.19 ZVx TRIGger-Subsystem The TRIGger subsystem is used to synchronize tasks performed by the instrument and events. This allows to control and synchronize the start of a sweep. An external trigger signal can be applied to the rear panel connector. COMMAND TRIGger [:SEQuence] :SOURce :TIMer :RTCLock :HOLDoff :SLOPe :LINK PARAMETER UNIT IMMediate | EXTernal | LINE | TIMer | MANual | RTCLock 0...23, 0...59, 0...
ZVx TRIGger-Subsystem TRIGger[:SEQuence]:HOLDoff This command defines the length of the trigger delay. TRIGger[:SEQuence]:HOLDoff Syntax: Example: Features: ::= 0...100s. "TRIG:HOLD 500us" *RST value: SCPI: 0s conforming TRIGger[:SEQuence]:SLOPe This command selects the edge of the trigger signal.
Instrument Model and Command Processing ZVx 3.7 Instrument Model and Command Processing The model shown in Fig. 3-2 visualizes the instrument from the point of view of servicing IEC-bus commands. The individual components work independent of each other and simultaneously. They communicate with each other by means of so-called "messages". Input unit with IEC Bus input puffer Command recognition Data set Status reportingsystem Instrument hardware IEC Bus Output unit with output buffer Fig.
ZVx 3.7.2 Instrument Model and Command Processing Command Recognition The command recognition analyses the data received from the input unit. It proceeds in the order in which it receives the data. Only a DCL is serviced with priority, a GET (Group Execute Trigger), e.g., is only executed after the commands received before as well. Each recognized command is immediately transferred to the data set but without being executed there at once.
Instrument Model and Command Processing 3.7.5 ZVx Output Unit The output unit collects the information requested by the controller, which it receives from the data set management. It processes it according to the SCPI rules and makes it available in the output buffer. The output buffer has a size of 4096 characters. If the information requested is longer, it is made available "in portions" without this being recognized by the controller.
ZVx Status Reporting System 3.8 Status Reporting System The status reporting system (cf. Fig. 3-4) stores all information on the present operating state of the instrument, e.g. that the instrument presently carries out an AUTORANGE and on errors which have occurred. This information is stored in the status registers and in the error queue. The status registers and the error queue can be queried via IEC bus. The information is of a hierarchical structure. The register status byte (STB) defined in IEEE 488.
Status Reporting System ZVx CONDition part The CONDition part is directly written into by the hardware or the sum bit of the next lower register. Its contents reflects the current instrument status. This register part can only be read, but not written into or cleared. Its contents is not affected by reading. PTRansition part The Positive-TRansition part acts as an edge detector. When a bit of the CONDition part is changed from 0 to 1, the associated PTR bit decides whether the EVENt bit is set to 1.
ZVx 3.8.
Status Reporting System ZVx 3.8.3 Description of the Status Registers 3.8.3.1 Status Byte (STB) and Service Request Enable Register (SRE) The STB is already defined in IEEE 488.2. It provides a rough overview of the instrument status by collecting the pieces of information of the lower registers. It can thus be compared with the CONDition part of an SCPI register and assumes the highest level within the SCPI hierarchy.
ZVx 3.8.3.2 Status Reporting System IST Flag and Parallel Poll Enable Register (PPE) By analogy with the SRQ, the IST flag combines the entire status information in a single bit. It can be queried by means of a parallel poll (cf. Section 3.8.4.3) or using command "*IST?". The parallel poll enable register (PPE) determines which bits of the STB contribute to the IST flag. The bits of the STB are ANDed with the corresponding bits of the PPE, with bit 6 being used as well in contrast to the SRE.
Status Reporting System 3.8.3.4 ZVx STATus:OPERation Register In the CONDition part, this register contains information on which actions the instrument is being executing or, in the EVENt part, information on which actions the instrument has executed since the last reading. It can be read using commands "STATus:OPERation:CONDition?" or "STATus:OPERation[:EVENt]?". Table 3-4 Meaning of the bits used in the STATus.OPERation register Bit No.
ZVx 3.8.3.5 Status Reporting System STATus:QUEStionable-Register This register contains information on questionable instrument states. Such states can occur, e.g. if the instrument is operated outside its specifications. It can be read using commands STATus:QUEStionable:CONDition? or STATus:QUEStionable[:EVENt]? Table 3-5 Meaning of the bits used in the STATus:QUEStionable register Bit No. Meaning 0 VOLTage This bit is set if a questionable voltage occurs.
Status Reporting System 3.8.3.6 ZVx STATus:QUEStionable:LIMit Register This register provides information about whether a limit value (upper limit, lower limit) for one of the memory traces (Trace 1, ... Trace 4) is exceeded. The register can be queried with the commands STATus:QUEStionable:LIMit[:EVENt?] and STATus:QUEStionable:LIMit:CONDition?.
ZVx 3.8.4 Status Reporting System Application of the Status Reporting System In order to be able to effectively use the status reporting system, the information contained there must be transmitted to the controller and further processed there. There are several methods which are represented in the following. 3.8.4.1 Service Request, Making Use of the Hierarchy Structure Under certain circumstances, the instrument can send a service request (SRQ) to the controller.
Status Reporting System 3.8.4.3 ZVx Parallel Poll In a parallel poll, up to eight instruments are simultaneously requested by the controller by means of a single command to transmit 1 bit of information each on the data lines, i.e., to set the data line allocated to each instrument to logically "0" or "1".
ZVx 3.8.5 Status Reporting System Reset Values of the Status Reporting System Table 3-7 comprises the different commands and events causing the status reporting system to be reset. None of the commands, except for *RST and SYSTem:PRESet influences the functional instrument settings. In particular, DCL does not change the instrument settings.
Softkeys – IEC/IEEE-bus-commands 3.9 ZVx Softkeys and Related IEC/IEEE BUS Commands The following list contains the IEC/IEEE-bus commands of the ZVR arranged according to the softkey menu structure (Section 2.2). Submenus are visualized by indentations. The function of the softkeys is described in Chapter 2, Manual Operation (for page numbers refer to the alphabetical softkey list – keyword "Softkey" – in the index). The remote control commands are listed in Section 3.6 (see Annex C). 3.9.
ZVx Softkeys – IEC/IEEE-bus-commands KEEP STOP FREQ CALCulate:TRANsform:TIME:LPASs KFSTop KEEP FREQ STEP WIDTH CALCulate:TRANsform:TIME:LPASs KDFRequency USE MIN STEP WIDTH CALCulate:TRANsform:TIME:LPASs MINStep LOWPASS DC S-PARAM CALCulate:TRANsform:TIME:LPASs:DCSPara NO PROFILING CALCulate:TRANsform:TIME:WINDow RECT LOW FIRST SIDELOBE CALCulate:TRANsform:TIME:WINDow HAMMing NORMAL PROFILE CALCulate:TRANsform:TIME:WINDow HANNing STEEP FALLOFF CALCulate:TRANsform:TIME:WINDow BOHMan ARBITRAR
Softkeys – IEC/IEEE-bus-commands DEF MIXER MEAS ZVx -- RF= BASE FREQ SENSe[1...4]:FREQuency:CONVersion:MIXer:FUNDamental RF LO= BASE FREQ SENSe[1...4]:FREQuency:CONVersion:MIXer:FUNDamental LO IF= BASE FREQ SENSe[1...4]:FREQuency:CONVersion:MIXer:FUNDamental LO EXT SRC1/SRC2 SENSe[1...4]:FREQuency:CONVersion:MIXer:LOEXternal SOURce1|SOURce2 FIXED RF FIXED LO FIXED IF SEL BAND – + ARBITRARY DEF ARBITRARY ARBITRARY SYST FREQ EXT SRC CONFIG COMPRESS SOI TOI IF SENSe[1...
ZVx Softkeys – IEC/IEEE-bus-commands INT SRC EXT SRC1 EXT SRC2 SOI DEF SOI MEAS SOURce[1..4]:FREQuency:NLINear:COMP INT SOURce[1..4]:FREQuency:NLINear:COMP ESRC1 SOURce[1..4]:FREQuency:NLINear:COMP ESRC2 SENSe[1..4]:FUNCtion[:ON] ‘XFRequency:NLINear SOI’ -- SRC POWER MAX LIMIT SOURce[1..4]:POWer:NLINear:SOI:RANGe:UPPer SRC POWER MIN LIMIT SOURce[1..4]:POWer:NLINear:SOI:RANGe:LOWer SETTLING TIME SENSe[1..
Softkeys – IEC/IEEE-bus-commands SWEEP MODE FREQUENCY SWEEP ZVx -- SENSe[1..4]:FUNCtion[:ON] ‘XFR:POW:...’ TIME SWEEP SENSe[1..4]:FUNCtion[:ON] ‘XTIM:POW:...’ POWER SWEEP SENSe[1..4]:FUNCtion[:ON] ‘XPOW:POW:...’ FAST MODE SENSe[1..4]:DETector:[FUNCtion] FAST | NORMAL -SETUP GENERAL SETUP GPIB ADDRESS -- SYSTem:COMMunicate:GPIB[:SELF]:ADDRess 0...
ZVx Softkeys – IEC/IEEE-bus-commands SERVICE FUNCTION DIAGnostic:SERVice:FUNCtion ,,,, ENTER PASSWORD SYSTem:PASSword[:CENable] -INFO FIRMWARE VERSIONS *IDN? HARDWARE + OPTIONS *OPT? 1043.0009.50 3.
Softkeys – IEC/IEEE-bus-commands 3.9.2 ZVx COPY Key Group HCOPy[:IMMediate<1|2>] COPY -SETTINGS COPY SCREEN COPY TRACE HCOPy:ITEM:ALL HCOPy:ITEM:WINDow<1...4><1|2>:TRACe:STATe ON | OFF HCOPy:ITEM:WINDow<1...
ZVx Softkeys – IEC/IEEE-bus-commands 3.9.
Softkeys – IEC/IEEE-bus-commands ZVx -- PAGE UP -- PAGE DOWN MMEMory:COMMent EDIT COMMENT -- ASCII FILE ASCII TOUCHSTONE SUPER COMPACT FORMat:DEXport ASCii FORMat:DEXport TOUChstone FORMat:DEXport SCOMpact REAL AND IMAGINARY FORMat:DEXport:FORMat COMPlex LIN MAG AND PHASE FORMat:DEXport:FORMat MLPHase dB MAG AND PHASE FORMat:DEXport:FORMat MDPHase APEND NEW FORMat:DEXport:MODe NEW | APPend DEC SEP .
ZVx Softkeys – IEC/IEEE-bus-commands -- RECALL MMEMory:LOAD:STATe 1, EDIT NAME SET PATH A:\... MMEMory:CDIRectory ‘A:\’ SET PATH C:\... MMEMory:CDIRectory ‘C:\’ SEL ITEMS TO RECALL -- ENABLE ALL ITEMS MMEMory:SELect[:ITEM]:ALL DISABLE ALL ITEMS MMEMory:SELect[:ITEM]:NONE MMEMory:SELect[:ITEM]:DEFault DEFAULT CONFIG MMEMory:LOAD:AUTO 1, AUTO RECALL 3.9.4 STATUS Key Group Gerätenachricht "Go to LOCAL (GTL)" LOCAL *RST PRESET USER 1043.0009.50 -- 3.
Softkeys – IEC/IEEE-bus-commands 3.9.5 ZVx STIMULUS Key Group START SENSe[1..4]:FREQuency:STARt SOURCe[1..4]:POWer:STARt (Frequenzsweep) (Leistungssweep) STOP SENSe[1..4]:FREQuency:STOP SOURCe[1..4]:POWer:STOP (Frequenzsweep) (Leistungssweep) SENSe[1..4]:FREQuency:CENTer SOURCe[1..4]:POWer:CENTer (Frequenzsweep) (Leistungssweep) SENSe[1..4]:FREQuency:SPAN SOURCe[1..
ZVx Softkeys – IEC/IEEE-bus-commands DEF TRIGGER IMMEDIATE EXTERNAL LINE PERIODIC TIMER REAL TIME CLOCK -- TRIGger[:SEQuence]:SOURce IMMediate TRIGger[:SEQuence]:SOURce EXTernal TRIGger[:SEQuence]:SOURce LINE TRIGger[:SEQuence]:SOURce TIMer TRIGger[:SEQuence]:SOURce RTCLock TRIGger[:SEQuence]:SOURce MANual MANUAL MANUAL TRIGGER *TRG TRIGGER DELAY TRIGger[:SEQuence]:HOLDoff TRIGGER SWEEP/POINT SLOPE POS/NEG EDIT TIMER PERIOD EDIT RTC TRIG TIME TRIGger[:SEQuence]:LINK 'SWEE
Softkeys – IEC/IEEE-bus-commands ZVx -SOURCE POWER SLOPE SOURce:POWer[:LEVel][:IMMediate][:AMPLitude] SOURce:POWer[:LEVel][:IMMediate]:SLOPe CAL a1 POWER SOURce:POWer[:LEVel][:IMMediate]:CAMPlitude:A1 CAL a2 POWER SOURce:POWer[:LEVel][:IMMediate]:CAMPlitude:A2 STEP ATT a1 STEP ATT b1 STEP ATT b2 STEP ATT a2 STEP ATT a1 AND a2 FREQUENCY OUTPut1:ATTenuation INPut1:ATTenuation INPut2:ATTenuation
ZVx Softkeys – IEC/IEEE-bus-commands SENSe[1..4]:AVERage:CLEar AVERAGE RESTART [SENSe[1...4]:]BANDwidth|BWIDth[:RESolution] IF BANDWIDTH 3.9.7 MARKER Key Group -- MARKER CALCulate[1..4]:MARKer[1..8]:X MARKER 1..8 CALCulate[1..4]:MARKer[1..8]:TRACe CHDATA|CHMEM MARKER DATA/MEM COUPLED MARKERS CALCulate[1..4]:MARKer[1..8]:COUPled[:STATe] ON | OFF MARKER CONVERS -- S 1/S Z Z/Z0 Y Y/Y0 CALCulate[1..4]:MARKer[1..8]:TRANsform:COMPlex S CALCulate[1..
Softkeys – IEC/IEEE-bus-commands GROUP DELAY ZVx CALCulate[1..4]:MARKer[1..8]:FORMat GDELay LIN MAG AND PHASE CALCulate[1..4]:MARKer[1..8]:FORMat MLPHase dB MAG AND PHASE CALCulate[1..4]:MARKer[1..8]:FORMat MDPHase REAL AND IMAGINARY CALCulate[1..4]:MARKer[1..8]:FORMat COMPlex L C RLC ELEMENTS ALL MARKER OFF MARKER CONT/DISCR CALCulate[1..4]:MARKer[1..8]:FORMat L CALCulate[1..4]:MARKer[1..8]:FORMat C CALCulate[1..4]:MARKer[1..8]:FORMat RLC CALCulate[1..4]:MARKer[1..8]:AOFF CALCulate[1..
ZVx Softkeys – IEC/IEEE-bus-commands DEFINE B’DFILTER BANDPASS BANDSTOP WIDTH -- CALCulate[1...4]:MARKer[1...8]:FUNCtion:BWIDth:MODE BPASs CALCulate[1...4]:MARKer[1...8]:FUNCtion:BWIDth:MODE BSTOp CALCulate[1...4]:MARKer[1...8]:FUNCtion:BWIDth QUALITY FACTOR CALCulate[1...4]:MARKer[1...8]:FUNCtion:QFACtor SHAPE FACT 60dB / 3dB CALCulate[1...4]:MARKer[1...8]:FUNCtion:SFACtor , SHAPE FACT 60dB / 6dB CALCulate[1...4]:MARKer[1...
Softkeys – IEC/IEEE-bus-commands 3.9.8 ZVx CHANNEL Key Group INSTrument[:SELect] CHANNEL<1..4> CH1..CH4 3.9.9 RESPONSE Key Group -- MEAS S11 REFL PORT1 [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...4]:]FUNCtion[:ON] "XFR:POW:S11" "XPOW:POW:S11" "XTIM:POW:S11" S21 TRANS FWD [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...4]:]FUNCtion[:ON] "XFR:POW:S21" "XPOW:POW:S21" "XTIM:POW:S21" S12 TRANS REV [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...
ZVx Softkeys – IEC/IEEE-bus-commands COMPLEX CONVERS S 1/S Z/Z0 Z Y/Y0 Y K-FACTOR µ1-FACTOR µ2-FACTOR CALCulate[1...4]:TRANsform:COMPlex S CALCulate[1...4]:TRANsform:COMPlex SINV CALCulate[1...4]:TRANsform:COMPlex ZREL CALCulate[1...4]:TRANsform:COMPlex Z CALCulate[1...4]:TRANsform:COMPlex YREL CALCulate[1...4]:TRANsform:COMPlex Y [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1...4]:]FUNCtion[:ON] [SENSe[1..
Softkeys – IEC/IEEE-bus-commands L C PHASE UNWRAP ZVx CALCulate[1...4]:FORMat L CALCulate[1...4]:FORMat C CALCulate[1...4]:FORMat UPHase -SCALE AUTOSCALE SCALE/DIV DISPlay[:WINDow[1...4]]:TRACe[1...4]:Y[:SCALe] :AUTO ONCE DISPlay[:WINDow[1...4]]:TRACe[1...4]:Y[:SCALe] :PDIVision REFERENCE VALUE DISPlay[:WINDow[1...4]]:TRACe[1...4]:Y[:SCALe] :RLEVel REFERENCE POSITION DISPlay[:WINDow[1...4]]:TRACe[1...4]:Y[:SCALe] :RPOSition MAX VALUE MIN VALUE ADD CONSTANT DISPlay[:WINDow[1...
ZVx CHARTER Softkeys – IEC/IEEE-bus-commands DISPlay[:WINDow<1...4>]:DIAGram CHARter -DISPLAY SINGLE CHANNEL DUAL CHAN OVERLAY DUAL CHAN SPLIT QUAD CHAN OVERLAY DISPlay:FORMat SINGle DISPlay:FORMat DOVerlay DISPlay:FORMat DSPLit DISPlay:FORMat QOVerlay QUAD CHAN DUAL SPLIT DISPlay:FORMat QDSPlit QUAD CHAN QUAD SPLIT DISPlay:FORMat QQSPlit EXPAND DISPlay:FORMat:EXPand ON|OFF -TRACE DATA TO MEMORY SHOW DATA SHOW MEM SHOW MATH SMOOTHING SMOOTHING APERTURE DEFINE MATH 1043.0009.
Softkeys – IEC/IEEE-bus-commands 3.9.10 ZVx CAL Key Group -- CAL -- START NEW CAL FULL TWO PORT -- PORT 1 CONNECTOR -- N 50 Ω FEMALE [SENSe[1...4]:]CORRection:COLLect:CONNection[1|2] N50FEMALE N 50 Ω MALE [SENSe[1...4]:]CORRection:COLLect:CONNection[1|2] N50MALE N 75 Ω FEMALE [SENSe[1...4]:]CORRection:COLLect:CONNection[1|2] N75FEMALE N 75 Ω MALE [SENSe[1...4]:]CORRection:COLLect:CONNection[1|2] N75MALE SMA FEMALE [SENSe[1...4]:]CORRection:COLLect:CONNection[1|2] SMAFEMALE [SENSe[1...
ZVx Softkeys – IEC/IEEE-bus-commands MATCH PORT 2 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] MATCH2 SLIDE PORT 1 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] SLIDE1 SLIDE PORT 2 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] SLIDE2 APPLY CAL [SENSe[1...4]:]CORRection:COLLect:METHod TRM TRM THROUGH [SENSe[1...4]:]CORRection:COLLect[:ACQuire] THRough REFLECT PORT 1 [SENSe[1...4]:]CORRection:COLLect: ACQuire REFL1 REFLECT PORT 2 [SENSe[1...
Softkeys – IEC/IEEE-bus-commands [SENSe[1...4]:]CORRection:COLLect:METHod TNA TNA THROUGH (TNA) ATTEN APPLY CAL [SENSe[1...4]:]CORRection:COLLect[:ACQuire] THRough [SENSe[1...4]:]CORRection:COLLect[:ACQuire] ATT [SENSe[1...4]:]CORRection:COLLect:SAVE [SENSe[1...4]:]CORRection:COLLect:METHod TOSM TOSM THROUGH [SENSe[1...4]:]CORRection:COLLect[:ACQuire] OPEN PORT 1 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] OPEN1 OPEN PORT 2 [SENSe[1...
ZVx Softkeys – IEC/IEEE-bus-commands AUTOKAL FUNDAM´TAL [SENSe[1...4]:]CORRection:COLLect:METHod FUNDamental -- (ZVR, ZVRE, ZVC, ZVCE) FULL ONE PORT BOTH PORTS [SENSe[1...4]:]CORRection:COLLect:METHod FOPORT12 OPEN PORT 1 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] OPEN1 SHORT PORT 1 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] SHORT1 MATCH PORT 1 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] MATCH1 OPEN PORT 2 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] OPEN2 SHORT PORT 2 [SENSe[1...
Softkeys – IEC/IEEE-bus-commands ZVx (ZVR, ZVRE, ZVC, ZVCE) ONE PATH TWO PORT FORWARD REVERSE [SENSe[1...4]:]CORRection:COLLect:METHod FOPTport [SENSe[1...4]:]CORRection:COLLect:METHod ROPTport OPEN PORT 1 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] OPEN1 SHORT PORT 1 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] SHORT1 MATCH PORT 1 [SENSe[1...4]:]CORRection:COLLect[:ACQuire] MATCH1 THROUGH [SENSe[1...4]:]CORRection:COLLect[:ACQuire] THRough OPEN PORT 2 [SENSe[1...
ZVx Softkeys – IEC/IEEE-bus-commands TRANS NORM [SENSe[1...4]:]CORRection:COLLect:METHod FTRANS FORWARD [SENSe[1...4]:]CORRection:COLLect:METHod RTRANS REVERSE THROUGH APPLY CAL [SENSe[1...4]:]CORRection:COLLect[:ACQuire] THRough [SENSe[1...4]:]CORRection:COLLect:SAVE --(ZVR, ZVRE, ZVC, ZVCE) REFL NORM [SENSe[1...4]:]CORRection:COLLect:METHod REFL12 BOTH PORTS [SENSe[1...4]:]CORRection:COLLect:METHod REFL1 PORT 1 [SENSe[1...4]:]CORRection:COLLect:METHod REFL2 PORT 2 OPEN PORT 1 [SENSe[1.
Softkeys – IEC/IEEE-bus-commands ZVx [SENSe[1...4]:]CORRection:COLLect:METHod FTRans (ZVRL) TRANS NORM [SENSe[1...4]:]CORRection:COLLect:METHod FOPTport FORWARD [SENSe[1...4]:]CORRection:COLLect[:ACQuire] THROUGH THRough [SENSe[1...4]:]CORRection:COLLect:SAVE APPLY CAL [SENSe[1...4]:]CORRection:COLLect:METHod REFL1 (ZVRL) REFL NORM [SENSe[1...4]:]CORRection:COLLect[:ACQuire] OPEN1 OPEN PORT 1 [SENSe[1...4]:]CORRection:COLLect:SAVE APPLY CAL [SENSe[1...
ZVx Softkeys – IEC/IEEE-bus-commands START NEW POWER CAL -- CAL a1 POWER SOURce:POWer[:LEVel][:IMMediate]:CAMPlitude:A1 CAL a2 POWER SOURce:POWer[:LEVel][:IMMediate]:CAMPlitude:A2 CAL b1 POWER [SENSe[1...4]:]CORRection:POWer:ACQuire B1 CAL b2 POWER [SENSe[1...
ZVx Selftest 4 Maintenance and Troubleshooting 4.1 Maintenance 4.1.1 Mechanical Maintenance The network analyzer does not require any mechanical maintenance. The front panel should be cleaned occasionally using a soft humid cloth. 4.1.2 Electrical Maintenance 4.1.2.1 Testing the Generator Level It is recommended to check the accuracy according to section 5 every two years.
Selbsttest ZVx 4.2 Monitoring the Function 4.2.1 Switch-on Test After the instrument has been switched on, a self test of the processor functions is performed first. This is followed by initialization of the transputer network, which then controls the analog modules. 4.2.2 Monitoring the Synthesizers and the Level Control Note: The current firmware version doesn’t contain the error messages described below.
ZVx Selftest 4.3 Function Description of the Complete Instrument The members of the ZVR/ZVC families are vector network analyzers with three measurement channels (ZVRE, ZVRL, ZVCE) or four measurement channels (ZVR, ZVC). • A Test Set with SWR bridges, power splitters, RF switches and level detectors makes for separation of the test signal, feeding-in and switchover of the generator signal and measurement of the generator level. • Generation of the test signal is accomplished in three modules, i.e.
Selbsttest ZVx The ZVRL, on the other hand, is a unidirectional network analyzer with only one SWR bridge without RF switch. Therefore, the ZVRL only permits measurement of the forward S-parameters (S11 and S21). In order to determine the reverse Sparameters (S22 and S12) as well, it is necessary to turn round the DUT when using the ZVRL. 4.3.1.
ZVx 4.3.1.5 Selftest Local The Local module provides the LO signals for the two mixers in the front end channels (LO1 signal for the 1st mixer, LO2 signal for the 2nd mixer). In addition, it contains the reference frequency source from which it generates the reference signal for the synthesizers (Synthesizer modules) and the signal for generation of the sampling signals in the converter modules.
Selbsttest 4.3.3 ZVx Processor Structure In addition to a 586 CPU, the network analyzer also comprises three 32-bit transputers T805 and one 16-bit transputer T225. Two DSPs are provided for digital signal processing. The 586 CPU handles the complete data exchange with the peripheral devices, such as e.g. keyboard entry, display of the softkeys and operation via IEC bus. Irrespective of this, the transputers control the measurement run, consider correction factors and represent the trace on the display.
ZVx Selftest 4.4 Self test The current firmware version does not support an automatic self test yet. However, the necessary hardware facilities are provided and can be used for troubleshooting with the aid of service functions (see Service Manual). Each synthesizer and signal module contains one or two 1-out-of-8 analog multiplexer which selects up to 16 test voltages via buffer amplifier and applies them to the common test channel.
ZVx Measuring Instruments and Accessories 5 Testing the Rated Specifications 5.1 Measuring Instruments and Accessories (R&S ZVR, R&S ZVRE, R&S ZVRL) Item Type of Instrument Required Specifications Appropriate Device R&S Order No. Use 1 Modulation analyzer 1 MHz to 4 GHz R&S FMB Opt. R&S FMA-B8 Opt.R&S FMA-B10 856.5005.52 855.9007.55 856.3502.52 5.2.1.1 5.2.1.4 5.2.1.5 2 Power meter 10 Hz to 4 GHz R&S NRVD with power sensor R&S NRV-Z51 857.8008.02 828.3818.02 5.2.1.6 5.2.1.
Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) 5.2 ZVx Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) The rated specifications of the network analyzer are checked after a warm-up time of at least 30 minutes. This makes sure that the guaranteed data are observed. The values given in the following sections are not guaranteed, only the technical data of the data sheet are binding. 5.2.1 Testing the Generator Specifications 5.2.1.
ZVx Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Measurement Set test frequencies according to test report. Measure at twice and three times the test frequency and calculate the difference from the measured value at the test frequency, report the worse of the two values.
Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Measurement: ZVx Set test frequencies according to test report. Mixer range up to 750 MHz: For fo < 50 MHz LO=RF+fo (fo = test frequency) RF = 63.125 MHz fo = 50 MHz to < 150 MHz RF = 252.5 MHz fo = 150 MHz to 750 MHz RF = 1010 MHz Perform measurements for f = 2*RF - LO and f = 3*RF - 2*LO.
ZVx 5.2.1.5 Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Residual FM Test equipment: Modulation meter FMB, matching pad RAM for 75 Test setup: test set Connect modulation meter (operating mode DEMOD FM DET RMS 10 Hz to 3 kHz) to PORT1 of the network analyzer (RAM to FMB for 75 ).
Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Reference measurement: CENTER 100MHz Port 1: Port 2: OUTPUT a1: Read the level on power meter. Measurement: -10 dBm ±0,5 dB -10 dBm ±0,5 dB -10 dBm ±0,5 dB ZVx with Opt. B10 3 dBm ±0,5 dB -10dBm±0,5dB 3 dBm ±0,5 dB Set test frequencies according to test report, read the level on power meter. Calculate the difference between the measured level and the reference level.
ZVx Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Measurement: Set test frequencies and levels according to test report, read the level on the power meter. Permissible deviations referred to the value at -10 dBm (+3 dBm at PORT 1 with Opt. R&S ZVR-B10): f = 40 kHz to 4 GHz +10 to –5 dB –5 dB to –15 dB < 0.4 dB < 0.6 dB 5.2.1.7.
Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) ZVx Alternative Measurement for R&S ZVR (firmware version 1.50 and higher): Test equipment: Test cable ZV-Z11, Calibration kit ZV-Z21, for 75 and matching pad RAM Test setup: test set: Calibration kit ZCAN-75 Connect test cable between PORT2 and Output a1 (for 75 : screw 75 male, RAM and 50 through female to PORT2) through Settings at the network analyzer: PRESET SWEEP MEAS SERVICE FUNCTION MARKER LOG SWEEP S22 2.13.1.1.
ZVx Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Measurement: Set test frequencies according to test report. Read out marker value on the ZVx Permissible deviation from the applied nominal level (–10 dBm) at PORT1 or PORT2, respectively: Passive test set: Measurement R&S ZVR-B25: 5.2.2.
Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Measurement: ZVx Set test frequencies and levels according to test report, report measurement results and subtract the reference values. Deviation from reference value (-10 dBm): 20 kHz to 200 kHz 200 kHz 5.2.2.3 Permissible deviation: +10 dB to +3 dB + 3 dB .to -15 dB <1 dB <0.2 dB +10 dB to +3 dB + 3 dB to -5 dB <1 dB <0.2 dB - 5 dB to -60 dB <0.05 dB Noise Level Test equipment: Test cable ZV-Z11 (ZV-Z12 for 75 (ZCAN for 75 test set).
ZVx 5.2.2.4 Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Matching Input b1 and Input b2 (Only with Option External Measurements R&S ZVR-B25) Test equipment, Power Splitter RVZ, Calibration Kit ZV-Z21, Test Port Cable pair ZV-Z11 test set 50 : Test equipment, Power Splitter RVZ, Calibration Kit ZV-Z22, Test Port Cable pair ZV-Z12, 2 N-adapters 50/75 test set 75 : Test setup: External On ZV R a1 b1 b2 THRU RVZ Kabel Kabel Block diagram for measuring the matching of input b1.
Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) ZVx Alternative Measurement (firmware version 1.50 and higher): Test equipment, Calibration kit ZV-Z21, pair of test cables ZV-Z11. test set 50 : Test equipment, Calibration kit ZV-Z21, pair of test cables ZV-Z11, matching pad RAM, calibration kit ZCAN-75.
ZVx Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) 5.2.3 Testing the Test Set Specifications 5.2.3.1 Matching to PORT1 and PORT2 • R&S ZVR, R&S ZVRE Test equipment test set 50 : Calibration Kit ZV-Z21, Test Port Cable pair ZV-Z11 Test equipment Calibration Kit ZV-Z22, Test Port Cable pair ZV-Z12 test set 75 : Test setup: Test cable between PORT1 and PORT2.
Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) • ZVx R&S ZVRL Measurement PORT2: As with R&S ZVR and R&S ZVRE Measurement PORT1 With further network analyzer ZVx as with R&S ZVR and R&S ZVRE. Measurement: Set test frequencies according to test report. Record return loss values. Test frequency: Return loss PORT1 50 5.2.3.
ZVx 5.2.3.3 Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) Testing the Attenuators Test equipment: Connecting cable ZV-Z11 (50 Test setup: ) or ZV-Z12 (75 ) Connect cable between PORT1 and PORT2.
Test Sequence (R&S ZVR, R&S ZVRE, R&S ZVRL) 5.2.3.4 ZVx Crosstalk Test equipment: 2 N-short-circuits (SHORT male and SHORT female with THRU male from calibration kit ZV-Z21 or ZV-Z22) Test setup: Connect N-short-circuits to PORT1 and PORT2.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) 5.3 Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Table 5-1: Performance Test Report – Generator Specifications Item No. Characteristic 1 Frequency accuracy 500 MHz 800 MHz 1500 MHz 2300 MHz 3000 MHz 3999 MHz Measure according to section 5.2.1.1 Min. value Actual value Max. value Unit -0.98 –1.58 –2.89 –4.58 –5.98 –7.98 ___________ ___________ ___________ ___________ ___________ ___________ 0.98 1.58 2.89 4.58 5.98 7.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristic 2 Harmonics suppression with Opt. R&S ZVR-B10 Measure according to section Min. value ZVx Max. value Actual value Unit 5.2.1.2 Test set passive Test set active/passive Test set passive Test set active/passive 1043.0009.50 Source Level: Max.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristic 3 Spurious suppression R&S ZVRL R&S ZVR R&S ZVRE passive test set ZVx frequ.: Spurious: 10 kHz 63.115 MHz 63.105 MHz 100 kHz 63.025 MHz 62.925 MHz Unit 5.2.1.3 40 40 40 40 ___________ ___________ ___________ ___________ - dB dB dB dB 40 40 ___________ ___________ - dB dB 1 MHz 62.125 MHz 61.125 MHz 53.125 MHz 43.125 MHz 202.5 MHz 152.5 MHz 152.5 MHz 52.5 MHz 103.5 MHz 45.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristic Measure according to section 5 Residual FM 5.2.1.5 1 MHz 9.99 MHz 149.9 MHz 750 MHz 1000 MHz 2000 MHz 3000 MHz 4000 MHz 6 Level accuracy Port 1 test set passive Level: –10 dBm Min. value ZVx Max. value Actual value - ___________ ___________ ___________ ___________ ___________ ___________ ___________ ___________ –1 –1 –1 –1 –1 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristic 6 Level accuracy Port 2 test set passive Level: –10 dBm Measure according to section Actual value Max. value Unit 5.2.1.6 9 kHz 20 kHz 40 kHz 100 kHz 1 MHz 2.1 MHz 3 MHz 10 MHz 50 MHz 200 MHz 500 MHz 1000 MHz 1500 MHz 2000 MHz 2500 MHz 3000 MHz 3500 MHz 4000 MHz 6 Level accuracy Port 1 test set active Level: –10 dBm w. Opt. ZVR-B10: +3 dBm –1 –1 –1 –1 –1 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristic 6 Level accuracy Port 2 test set active Level: –10 dBm Measure according to section Min. value Actual value ZVx Max. value Unit 5.2.1.6 300 kHz 1 MHz 2.1 MHz 3 MHz 10 MHz 50 MHz 200 MHz 500 MHz 1000 MHz 1500 MHz 2000 MHz 2500 MHz 3000 MHz 3500 MHz 4000 MHz 6 Level accuracy Option External Measurements Level: –10 dBm w. Opt. ZVR-B10: +3 dBm –1 –1 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.
ZVx Item No. Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Characteristic 7 Level linearity R&S ZVR R&S ZVRE R&S ZVRL Ref. level: –10dBm +3 dBm with Opt. ZVR-B10 test set passive f = 40 kHz Measure according to section Min. value Max. value Actual value Unit 5.2.1.7 10dB 5dB –5dB –10dB –15dB test set active/passive 10.4 5.4 –5.4 –10.6 –15.6 ___________ ___________ ___________ ___________ ___________ 9.6 4.6 –4.6 –9.4 –14.4 dB dB dB dB dB 10.4 5.4 –5.4 –10.6 –15.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Table 5-2 Performance Test Report: ZVx Receiver specifications Measurement according to section Min. value Actual value Max.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Measurement according to section Min. value Actual value Max.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Measurement according to section ZVx Min. value Actual value Max.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristics 2 Linearity PORT1 Phase Reference: -10 dBm f = 1.5MHz Measurement according to section Linearity PORT1 Magnitude Reference: -10 dBm f = 4000 MHz Linearity PORT1 Phase Reference: -10 dBm f = 4000 MHz Linearity PORT2 Magnitude Reference: -10 dBm f = 1.5 MHz Linearity PORT2 Phase Reference: -10 dBm f = 1.5 MHz _________ _________ _________ _________ 6 1 0.4 0.4 degrees degrees degrees degrees –1 –0.2 –0.05 –0.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristics 2 Linearity PORT2 Magnitude Reference: -10 dBm f = 4000 MHz Measurement according to section Linearity PORT2 Phase Reference: -10 dBm f = 4000 MHz Min. value Actual value Max. value Unit –1 –0.2 –0.05 –0.05 _________ _________ _________ _________ 1 0.2 0.05 0.05 dB dB dB dB –6 –1 –0.4 –0.4 _________ _________ _________ _________ 6 1 0.4 0.4 degrees degrees degrees degrees 5.2.2.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristics 3 Noise level PORT2 R&S ZVR 75N R&S ZVRE 75N Test Set active 300 kHz 1 MHz 19 MHz 20 MHz 100 MHz 200 MHz 700 MHz 1000 MHz 2000 MHz 3000 MHz 4000 MHz 4 Matching Input b1 R&S ZVR R&S ZVRE Option External Measurements 400 kHz 1.9 MHz 2 MHz 100 MHz 1000 MHz 2000 MHz 3000 MHz 3500 MHz 4000 MHz 4 Matching Input b2 R&S ZVR R&S R&S ZVRE 400 kHz 1.
ZVx Table 5-3 Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Performance Test Report: Test Set Specifications Item No. Characteristics 1 Matching PORT1 Measurement according to section Min. value Actual value Max.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristics 1 Matching PORT2 Measurement according to section Min. value Actual value Max.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristics 3 Attenuators Option R&S ZVR–B21 ATT a1 f = 2000 MHz Measurement according to section ZVx Min. value Actual value Max. value Unit –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.1 2 2 2 2 2 2 dB dB dB dB dB dB dB dB –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.
ZVx Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristics 3 Attenuators Option R&S ZVR–B22 ATT a2 f = 4000 MHz Measurement according to section Min. value Actual value Max. value Unit –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.1 2 2 2 2 2 2 dB dB dB dB dB dB dB dB –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Item No. Characteristics 3 Attenuators Option R&S ZVR–B24 ATT b2 f = 1 MHz Measurement according to section ZVx Min. value Actual value Max. value Unit –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.1 2 2 2 2 2 2 dB dB dB dB dB dB dB dB –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.
ZVx Table 5-4 Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Performance Test Report: Crosstalk Measurement according to section Min. value Actual value Max. value Unit 20 kHz 201 kHz – – ___________ ___________ –90 –120 dB dB test set active/passive 300 kHz 2.5 MHz 5.
Performance Test Report (R&S ZVR, R&S ZVRE, R&S ZVRL) Measurement according to section ZVx Min. value Actual value Max. value Unit 9 kHz 201 kHz – – ___________ ___________ –90 –120 dB dB 300 kHz 2.5 MHz 5.
ZVx 5.4 Measuring Instruments and Accessories (ZVC, ZVCE) Measuring Instruments and Accessories (ZVC, ZVCE) Item Type of Instrument Required Specifications Appropriate Device R&S Order No. Use 1 Modulation analyzer 1 MHz to 5.2 GHz R&S FMB Opt. R&S FMA-B8 Opt. R&S FMA-B10 0856.5005.52 0855.9007.55 0856.3502.52 5.2.1.1 5.2.1.4 5.2.1.5 2 Power meter 20 kHz to 8 GHz R&S NRVD or R&S NRVS with sensor R&S NRV-Z51 R&S NRV-Z5 0857.8008.02 1020.1809.02 5.2.1.6 R&S RSG *) or R&S RSM 1009.4505.
Test Sequence (R&S ZVC, R&S ZVCE) 5.5 ZVx Test Sequence (R&S ZVC, R&S ZVCE) The rated specifications of the network analyzer are checked after a warm-up time of at least 30 minutes and after performing the reference oscillator adjustment, recording of detector characteristics and factory calibration. This makes sure that the guaranteed data are observed. The device settings quoted are PRESET settings.
ZVx Test Sequence (R&S ZVC, R&S ZVCE) Measurement Set test frequencies according to test report. Measure at twice and three times the test frequency and calculate the difference from the measured value at the test frequency, report the worse of the two values.
Test Sequence (R&S ZVC, R&S ZVCE) Measurement: ZVx Set test frequencies according to test report. Mixer range up to 750 MHz: For fo < 50 MHz LO=RF+fo (fo = test frequency) RF = 63.125 MHz fo = 50 MHz to < 150 MHz RF = 252.5 MHz fo = 150 MHz to 750 MHz RF = 1010 MHz Perform measurements for f = 2*RF – LO and f = 3*RF – 2*LO.
ZVx 5.5.1.5 Test Sequence (R&S ZVC, R&S ZVCE) Residual FM est equipment: Test setup: Modulation meter FMB Connect modulation meter (operating mode DEMOD FM DET RMS 10 Hz to 3 kHz) to PORT1 of the spectrum analyzer. Settings at the network analyzer: Measurement SWEEP SINGLE POINT CENTER Test frequency SOURCE POWER Maximum level SWEEP TIME 200 s MEAS INPUT Set test frequencies according to test report, read the residual FM values on the modulation meter.
Test Sequence (R&S ZVC, R&S ZVCE) 5.5.1.7 ZVx Level Linearity Test equipment: Power meter NRVD with power sensor NRV-Z5 Test setup: Connect power sensor to PORT1 or PORT2 of the network analyzer. Settings at the network analyzer: Measurement: SWEEP SINGLE POINT CENTER Test frequency SOURCE POWER Maximum value to minimum value SWEEP TIME 200 s MEAS INPUT a1 INPUT a2 Set test frequencies according to test report, read the level on the power meter.
ZVx 5.5.1.
Test Sequence (R&S ZVC, R&S ZVCE) ZVx 5.5.2 Testing the Receiver Specifications 5.5.2.1 Absolute Accuracy Test equipment: Test cable ZV-Z11 Calibration: Perform POWER CAL a1, a2. Test setup: Connect PORT1 to PORT 2 or Output a1 to INPUT b1 or to INPUT b2 via test cable.
ZVx 5.5.2.2 Test Sequence (R&S ZVC, R&S ZVCE) Linearity Test equipment: Attenuator RSM Test setup: Connect RSM between PORT1 and PORT2.
Test Sequence (R&S ZVC, R&S ZVCE) 4 GHz to 8 GHz Model 51, 52, 61, 62: 300 kHz to 4 GHz 4 GHz to 8 GHz ZVx 60 dB to 70 dB (ZVCE) <1 dB <6° 60 dB to 75 dB (ZVC) <1 dB <6° <1 dB <0.2 dB <6° <2° 45 dB to 55 dB (ZVCE) <1 dB <6° 45 dB to 60 dB (ZVC) <1 dB <6° +10 dB to +3 dB + 3 dB to 45 dB Deviation from reference value (–10 dBm): + 3 dB to 70 dB <0.2 dB <1° 70 dB to 80 dB (ZVCE) <1 dB <6° 70 dB to 85 dB (ZVC) <1 dB <6° <0.
ZVx Test Sequence (R&S ZVC, R&S ZVCE) Measurement: Set test frequencies according to test report. Read marker value on the network analyzer taking the SOURCE POWER (-10 dB) into account. Permissible noise values: Model 50, 60 20 kHz to 200 kHz 200 kHz to 20 MHz 20 MHz to 3 GHz 3 GHz to 4 GHz 4 GHz to 8 GHz 5.5.2.
Test Sequence (R&S ZVC, R&S ZVCE) Reference measurement: Measurement: ZVx One-port calibration including THRU over the complete frequency range (for measurement at b1 and b2 an extra calibration each). Set marker frequencies according to test report, measure b1 and b2. Record return loss values. Return loss: > 8 dB Alternative Measurement (firmware version 1.
ZVx Test Sequence (R&S ZVC, R&S ZVCE) 5.5.3 Testing the Test Set Specifications 5.5.3.1 Matching to PORT1 and PORT2 Test equipment Calibration Kit ZV-Z21, Test Port Cable pair ZV-Z11 Test setup: Test cable between PORT1 and PORT2.
Test Sequence (R&S ZVC, R&S ZVCE) Reference measurement: Measurement: ZVx Perform reflection normalization (CAL menu) at PORT1 or PORT2, respectively. Set marker to test frequencies according to test report. Record directivity values. Test frequency: 40 kHz to 5 MHz 5 MHz to 1.5 GHz 1.5 GHz to 4 GHz 4 GHz to 8 GHz Directivity: Mod. 50, 60 Mod. 52, 62 Mod. 51, 61 ------------------> 16 dB > 16 dB ----------> 30 dB > 30 dB > 8 dB > 30 dB > 30 dB > 30 dB > 8 dB 5.5.3.
ZVx Test Sequence (R&S ZVC, R&S ZVCE) Permissible deviations: 5.5.3.4 ATT a1, a2 ATT b1, b2 < 2 dB < 2 dB Crosstalk Test equipment: 2 N-short-circuits Test setup: Connect N-short-circuits to PORT1 and PORT2.
Performance Test Report (ZVC, ZVCE) ZVx 5.6 Performance Test Report (ZVC, ZVCE) Table 5-5: Performance Test Report – Generator Specifications Item No. Characteristics 1 Frequency accuracy Measuremt. according to section Min. value Actual value Max. value Unit 0.98 1.58 2.89 4.58 5.98 7.98 9.98 MHz MHz MHz MHz MHz MHz MHz 5.2.1.1 -0.98 -1.58 -2.89 -4.58 -5.98 -7.98 -9.98 500 MHz 800 MHz 1500 MHz 2300 MHz 3000 MHz 3999 MHz 4999 MHz 2 Harmon. suppression Source Level: max.
ZVx Item No. Performance Test Report (ZVC, ZVCE) Measuremt. according to section Min. value Actual value Max. value Unit 35 35 35 35 35 35 35 35 35 35 35 35 __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ - dB dB dB dB dB dB dB dB dB dB dB dB Source Level: max.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics Measuremt. according to section 1001 MHz 1501 MHz 2000 MHz 2500 MHz 3000 MHz 3500 MHz 4000 MHz 4010 MHz 5000 MHz 6000 NHz 7000 MHz 8000 MHz 3 Min. value Actual value Max.
ZVx Item No. Performance Test Report (ZVC, ZVCE) Characteristics 3000 MHz 3200 MHz 3310 MHz 3400 MHz 3600 MHz 3800 MHz 4000 MHz 4100 MHz 4500 MHz 5000 MHz 5100 MHz 5700 MHz 6300 MHz 6400 MHz 7200 MHz 8000 MHz 4 1043.0009.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics Measuremt. according to section 5 Residual FM 5.2.1.5 1 MHz 9.99 MHz 149.9 MHz 750 MHz 1000 MHz 2000 MHz 3000 MHz 4000 MHz 8000 MHz 6 Option External Measurements Level accuracy OUTPUT a1 Min. value Actual value Max. value Unit - __________ __________ __________ __________ __________ __________ __________ __________ __________ 1 1 2 5 5 10 20 20 40 Hz Hz Hz Hz Hz Hz Hz Hz Hz –1 –1 –1 –1 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 6 Level accuracy PORT1 Measuremt. according to section Min. value Actual value Max. value Unit –1 –1 –1 –1 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.5 –0.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics 7 Level linearity Reference: –10 dBm Measuremt. according to section ZVx Min. value Actual value Max. value Unit 9.6 4.6 –5.4 –10.8 –15.8 __________ __________ __________ __________ __________ 10.4 5.4 –4.6 –9.2 –14.2 dB dB dB dB dB 9.6 4.6 –5.4 –10.8 –15.8 __________ __________ __________ __________ __________ 10.4 5.4 –4.6 –9.2 –14.2 dB dB dB dB dB 9.6 4.6 –5.4 –10.8 –15.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 7 Level linearity Model 50 and 60 w. opt. ZVR-B10 Reference: 0 dBm Measuremt. according to section Min. value Actual value Max. value Unit 9.6 4.6 –5.4 –10.6 –15.6 __________ __________ __________ __________ __________ 10.4 5.4 –4.6 –9.4 –14.4 dB dB dB dB dB 9.6 4.6 –5.4 –10.6 –15.6 __________ __________ __________ __________ __________ 10.4 5.4 –4.6 –9.4 –14.4 dB dB dB dB dB 9.6 4.6 –5.4 –10.6 –15.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics 7 Level linearity Model 51 and 61 w. opt. ZVR-B10 Reference: 0 dBm Measuremt. according to section ZVx Min. value Actual value Max. value Unit 5.6 –4.4 –9.4 –14.6 –17.6 __________ __________ __________ __________ __________ 6.4 –3.6 –8.6 –13.4 –16.4 dB dB dB dB dB 5.6 –4.4 –9.4 –14.6 –17.6 __________ __________ __________ __________ __________ 6.4 –3.6 –8.6 –13.4 –16.4 dB dB dB dB dB 5.6 –4.4 –9.4 –14.6 –17.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 7 Level linearity Model 52 and 62 w. opt. ZVR-B10 Reference: 0 dBm Measuremt. according to section Min. value Actual value Max. value Unit 5.6 –4.4 –9.4 –14.6 –17.6 __________ __________ __________ __________ __________ 6.4 –3.6 –8.6 –13.4 –16.4 dB dB dB dB dB 5.6 –4.4 –9.4 –14.6 –17.6 __________ __________ __________ __________ __________ 6.4 –3.6 –8.6 –13.4 –16.4 dB dB dB dB dB 5.6 –4.4 –9.4 –14.6 –17.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics 8 Matching Output a1 Measuremt. according to section ZVx Min. value Actual value Max. value Unit - __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ __________ –8 –8 –8 –8 –8 –8 –8 –8 –8 –8 –8 –8 –8 –8 –8 –8 –8 dB dB dB dB dB dB dB dB dB dB dB dB dB dB dB dB dB 5.2.1.8 Only Option External Measurements 1043.
ZVx Table 5-6 Performance Test Report (ZVC, ZVCE) Performance Test Report: Receiver Specifications Item No. Characteristics 1 Absolute Accuracy PORT1 Level: –10 dBm Model 50, 51,60,61 All models 1 Model 50, 51,60,61 All models 1043.0009.50 Measuremt. according to section Min. value Actual value Max.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics 1 Absolute Accuracy Input b1 Level: –10 dBm Option Ext. Measureme nts 1 Option Ext. Measurements 1043.0009.50 ZVx Measuremt. according to section Actual value Max.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics Measuremt. according to section 3 Linearity model 50 and 60 Magnitude Reference: -20 dBm 5.2.2.2 Min. value Actual value Max. value Unit –1 –0.2 –0.2 _________ _________ _________ 1 0.2 0.2 dB dB dB –6 –2 –2 _________ _________ _________ 6 2 2 degrees degrees degrees –1 –0.2 –0.2 _________ _________ _________ 1 0.2 0.2 dB dB dB –6 –1 –1 _________ _________ _________ 6 1 1 degrees degrees degrees –1 –0.2 –0.
Performance Test Report (ZVC, ZVCE) ZVx Item No. Characteristics Measuremt. according to section 3 Linearity model 51, 52, 61, 62 Magnitude Reference: -10 dBm 5.2.2.2 Min. value Actual value Max. value Unit –0.2 –0.2 –0.2 _________ _________ _________ 0.2 0.2 0.2 dB dB dB –1 –1 –1 _________ _________ _________ 1 1 1 degrees degrees degrees –0.2 –0.2 –0.2 _________ _________ _________ 0.2 0.2 0.2 dB dB dB –1 –1 –1 _________ _________ _________ 1 1 1 degrees degrees degrees –0.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 4 Noise level b1 Model 50 and 60 Measuremt. according to section Noise level b2 Model 50 and 60 Noise level b1 Model 51, 52, 61, 62 Max.
Performance Test Report (ZVC, ZVCE) ZVx Measuremt. according to section Min. value Actual value Max.
ZVx Table 5-7 Performance Test Report (ZVC, ZVCE) Performance Test Report: Test Set Specifications Item No. Characteristics 1 Matching PORT1 Model 50 and 60 Measuremt. according to section Matching PORT2 Model 50 and 60 Max.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics 1 Matching PORT1 Model 51 and 61 ZVx Measuremt. according to section Matching PORT2 Model 51 and 61 Max.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 1 Matching PORT1 Model 52 and 62 Measuremt. according to section Matching PORT2 Model 52 and 62 Max.
Performance Test Report (ZVC, ZVCE) ZVx Measuremt. according to section Min. value Actual value Max.
ZVx Performance Test Report (ZVC, ZVCE) Measuremt. according to section Min. value Actual value Max.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics 3 Attenuators Option R&S ZVR–B21 ATT a1 f = 4000 MHz ZVx Measuremt. according to section Min. value Actual value Max. value Unit –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.1 2 2 2 2 2 2 dB dB dB dB dB dB dB dB –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 3 Attenuators Option R&S ZVR–B22 ATT a2 f = 4000 MHz Measuremt. according to section Min. value Actual value Max. value Unit –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.1 2 2 2 2 2 2 dB dB dB dB dB dB dB dB –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics 3 Attenuators Option R&S ZVR–B23 ATT b1 f = 4000 MHz ZVx Measuremt. according to section Min. value Actual value Max. value Unit –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.1 2 2 2 2 2 2 dB dB dB dB dB dB dB dB –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 3 Attenuators Option R&S ZVR–B24 ATT b2 f = 4000 MHz Measuremt. according to section Min. value Actual value Max. value Unit –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.1 2 2 2 2 2 2 dB dB dB dB dB dB dB dB –2 –0.1 –2 –2 –2 –2 –2 –2 _________ _________ _________ _________ _________ _________ _________ _________ 2 0.1 2 2 2 2 2 2 dB dB dB dB dB dB dB dB 5.2.
Performance Test Report (ZVC, ZVCE) Table 5-8 Performance Test Report: Item No. Characteristics 1 Crosstalk PORT1 Model 50 Crosstalk PORT2 Model 50 20 kHz 201 kHz 2.5 MHz 5.1 MHz 500 MHz 1000 MHz 2200 MHz 2700 MHz 3000 MHz 3300 MHz 3600 MHz 3900 MHz 4000 MHz 4500 MHz 5000 MHz 5500 MHz 6000 MHz 6500 MHz 7000 MHz 7500 MHz 8000 MHz 1043.0009.50 Crosstalk Measuremt. according to section Min. value Actual value Max.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 1 Crosstalk PORT1 Model 60 Measuremt. according to section Crosstalk PORT2 Model 60 20 kHz 201 kHz 2.5 MHz 5.1 MHz 500 MHz 1000 MHz 2200 MHz 2700 MHz 3000 MHz 3300 MHz 3600 MHz 3900 MHz 4000 MHz 4500 MHz 5000 MHz 5500 MHz 6000 MHz 6500 MHz 7000 MHz 7500 MHz 8000 MHz 1043.0009.50 Actual value Max.
Performance Test Report (ZVC, ZVCE) Item No. Characteristics 1 Crosstalk PORT1 Model 51 and 52 Measuremt. according to section ZVx Min. value Actual value Max. value Unit 5.2.4 Model 51 20 kHz – ___________ –84 dB Model 51 and 52 300 kHz 2.5 MHz 5.
ZVx Performance Test Report (ZVC, ZVCE) Item No. Characteristics 1 Crosstalk PORT1 Model 61 and 62 Measuremt. according to section Min. value Actual value Max. value Unit 5.2.4 Model 61 20 kHz – ___________ –84 dB Model61 and 62 300 kHz 2.5 MHz 5.
Performance Test Report (ZVC, ZVCE) Min. value Actual value Max. value Unit 20 kHz – ___________ –75 dB 300 kHz 2.5 MHz 5.
ZVx Measuring Equipment and Accessories (ZVM, ZVK) 5 Checking of Rated Specifications 5.1 Measuring Equipment and Accessories (ZVM, ZVK) Item Instrument type Required specifications Suitable instrument R&S Order No. Application 1 Spectrum analyzer 10 MHz to 20 GHz (ZVM) 10 MHz to 40 GHz (ZVK), IF output FSEK30 with FSE-B22 1088.3494.35 1106.3480.02 5.2.1.1 5.2.1.2 5.2.1.3 5.2.1.4 5.2.1.5 5.2.1.7 2 Modulation analyzer 10 MHz to 5.2 GHz FMB with opt. FMA-B8 856.5005.52 855.9007.55 5.2.
Test Procedure (ZVM & ZVK) 5.2 ZVx Test Procedure (ZVM & ZVK) The rated specifications of the network analyzer are checked after a warm-up time of at least one hour. Only this warmup ensures that the specifications are complied with. The values stated in the following are not guaranteed. Only the data sheet specifications shall be binding. In order to guarantee the specified data, the measured value has to be < specification - expanded uncertainty (k = 2, confidence level of 95%).
ZVx 5.2.1.2 Test Procedure (ZVM & ZVK) Harmonics Test equipment: FSEK30, test cable Test setup: ½ Connect FSEK30 (delta-marker mode) to PORT1 (PORT2) of the network analyzer.
Test Procedure (ZVM & ZVK) 5.2.1.3 ZVx Spurious Test equipment: FSEK30, test cable Test setup: ½ Connect FSEK30 (delta-marker mode) to PORT1 of the network analyzer. Settings on network analyzer: PRESET CENTER Measurement frequency SWEEP SINGLE POINT SWEEP TIME 255 s SOURCE POWER -20 dBm (minimum level) MEAS INPUT a1 Reference measurement: ½ Set marker 1 to generator frequency (fundamental) Measurement: ½ Set measurement frequencies according to test record.
ZVx 5.2.1.4 Test Procedure (ZVM & ZVK) Phase Noise Test equipment: Modulation meter FMB with option FMA-B8, FSEK30, BNC connecting cable Test setup: ½ Connect modulation meter (mode DEMOD PM PHASENOISE 10 kHz) to PORT1 of the network analyzer. Settings on network analyzer: PRESET Measurement: 1127.8500.
Test Procedure (ZVM & ZVK) 5.2.1.5 ZVx Residual FM Test equipment: Modulation meter FMB with option FMA-B8, FSEK30, BNC connecting cable Test setup: ½ Connect modulation meter (mode DEMOD FM DET RMS 10 Hz to 3 kHz) to PORT1 of the network analyzer Settings on network analyzer: PRESET Measurement: 1127.8500.
ZVx 5.2.1.6 Test Procedure (ZVM & ZVK) Level Accuracy Test equipment: Power Meter NRVD with sensor NRV-Z52 (ZVM), NRV-Z55 (ZVK), Female-female adapter from calibration kit ZV-Z32 (ZVM) or ZV-Z34 (ZVK) Test setup: ½ Connect power sensor to PORT1, PORT2 of the network analyzer.
Test Procedure (ZVM & ZVK) 5.2.1.7 ZVx Level Linearity Test equipment: FSEK30, test cable, BNC cable for reference frequency Test setup 50Ω: ½ Connect FSEK30 to PORT1 (PORT2) of the network analyzer. Synchronize FSEK30 with network analyzer. ½ Important: IF BW on FSEK30 < 1 kHz (digital bandwidths) Settings on network analyzer: PRESET SWEEP SINGLE POINT CENTER Measurement frequency SOURCE POWER Min. to max. value -20 dBm to -2/2/5 dBm, ZVM Min. to max.
ZVx Test Procedure (ZVM & ZVK) 5.2.2 Checking the Receiver Specifications 5.2.2.1 Absolute Accuracy Test equipment: Signal Generator SMR40 with option SMR-B11 Power Splitter PC 3.5 (ZVM) or Power Splitter PC 2.92 (ZVK) NRVD with sensor NRV-Z52 (ZVM), NRV-Z55 (ZVK) Connecting cable SMR40 => power splitter BNC cable to frequency synchronization. Test setup: ½ Synchronize SMR40 with network analyzer. ½ SMR40 frequency = measurement frequency. ½ Connect SMR40 to power-splitter input.
Test Procedure (ZVM & ZVK) 5.2.2.2 ZVx Linearity Test equipment: 20 dB attenuator PC 3.5, SMA (ZVM) or PC 2.92 (ZVM, ZVK), Test Cable ZV-Z14 (ZVM) or ZV-Z15 (ZVK), Female-female adapter from ZV-Z32 (ZVM) or ZV-Z34 (ZVK) Test setup: Connect test cable with 20 dB attenuator between PORT1 and PORT2.
ZVx 5.2.2.3 Test Procedure (ZVM & ZVK) Noise Level Test equipment: MATCH female from Calibration Kit ZV-Z32 (ZVM) or ZV-Z34 (ZVK) Calibration: ½ PRESET ½ SOURCE Level –20 dBm ½ Terminate Port 1 and Port 2 with match from ZV-Z32 or ZV-Z34. ½ MEAS : INPUT b1, DRIVE PORT 2 or INPUT b2, DRIVE PORT1 ½ Set all receiver step attenuators to 0 dB ½ IF bandwidth 10 Hz : AVG IF BW: 10 Hz Measurement: 1127.8500.
Test Procedure (ZVM & ZVK) 5.2.2.4 ZVx Match Input b1 and Input b2 (only with option ZVM-B23 / ZVK-B23 or ZVM-B24 / ZVK-B24) Test equipment: Calibration Kit ZV-Z32, pair of Test Cables ZV-Z14 (ZVM); Calibration Kit ZV-Z34, pair of Test Cables ZV-Z15 (ZVK) Test setup: Description for INPUT B2 (for INPUT B1 analogously) Connect test cable to PORT1, connect female-female adapter to male end.
ZVx Test Procedure (ZVM & ZVK) 5.2.3 Checking the Test Set Specifications 5.2.3.1 Match at PORT1 and PORT2 Test equipment: Calibration Kit ZV-Z32, pair of Test Cables ZV-Z14 (ZVM); Calibration Kit ZV-Z34, pair of Test Cables ZV-Z15 (ZVK) Test setup: Description for PORT2 (for PORT1 analogously) Connect test cable to PORT1, connect female-female adapter to male end.
Test Procedure (ZVM & ZVK) 5.2.3.2 ZVx Matching Reference Channel Inputs R1 and R2 Channel IN Test equipment: Calibration Kit ZV-Z32, pair of Test Cables ZV-Z14 (ZVM); Calibration Kit ZV-Z34, pair of Test Cables ZV-Z15 (ZVK) Test setup: Description for R2 Channel IN (for R1 Channel IN analogously) Connect test cable to PORT1. Settings on network analyzer: PRESET AVG IF BW 100 Hz Record one-port calibration (OSM) at PORT1 over the whole frequency range. Connect test cables (incl.
ZVx 5.2.3.3 Test Procedure (ZVM & ZVK) Raw Directivity Test equipment: OPEN, SHORT, MATCH female from Calibration Kit ZV-Z32 (ZVM), ZV-Z34 (ZVK) A broadband termination, e.g. from ZV-Z34, must be used for ZVK. Reference measurement: PRESET Connect OPEN female to Port1 (or Port2). MEAS: RATIO: WAVE QUANTITY: b1/a1 (Port1), b2/a2 (Port2) Normalizing: TRACE, DATA TO MEM, SHOW MATH (/) Connect MATCH to Port1 (or Port2). MARKER Measurement frequency Read measurement results and write them down.
Test Procedure (ZVM & ZVK) 5.2.3.4 ZVx Checking the Attenuators Test equipment: Test Cable ZV-Z14, female-female adapter PC 3.5 from ZV-Z32; Test Cable ZV-Z15, female-female adapter PC 2.92 from ZV-Z34 Test setup: Connect cable between PORT1 and PORT2.
ZVx 5.2.3.5 Dynamic Range Test equipment: ZVM: 2 PC 3.5 SHORT (e.g. SHORT male and SHORT female with THRU male from Calibration Kit ZV-Z32); ZVK: 2 PC 2.92 SHORT (e.g. SHORT male and SHORT female with THRU male from Calibration Kit ZV-Z34) Test setup: Connect short-circuits to PORT1 and PORT2. Settings on network analyzer: PRESET SWEEP FORMAT SOURCE POWER LIN SWEEP MAGNITUDE Maximum value acc.
Performance Test Record (ZVM) 5.3 ZVx Performance Test Record (ZVM) The indicated uncertainties refer to the proposed test setup / test procedure. The expanded measurement uncertainty amounts to k = 2 (confidence level of 95%, Gauss distribution). Additional measurement uncertainties, which are within the user’s responsibility, have not been taken into account (e.g. cable attenuation in harmonics measurements).
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 2 Harmonics 5.2.1.2 Specification min. value/dBc Measured value/dBc Uncertainty / dB PORT1 Measurement at source level 5 dBm (2 dBm with ZVM-B21) 1127.8500.60 ZVM frq. Harmonic: 10 MHz 20 MHz 30 MHz 23 23 ___________ ___________ 1.5 1.5 100 MHz 200 MHz 300 MHz 23 23 ___________ ___________ 1.3 1.3 500 MHz 1000 MHz 1500 MHz 23 23 ___________ ___________ 1.3 1.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 2 Harmonics 5.2.1.2 ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB PORT2 Measurement at source level 5 dBm (2 dBm with ZVM-B22) 1127.8500.60 ZVM frq. Harmonic: 10 MHz 20 MHz 30 MHz 23 23 ___________ ___________ 1.5 1.5 100 MHz 200 MHz 300 MHz 23 23 ___________ ___________ 1.3 1.3 500 MHz 1000 MHz 1500 MHz 23 23 ___________ ___________ 1.3 1.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 2 Harmonics 5.2.1.2 Specification min. value/dBc Measured value/dBc Uncertainty / dB PORT 1 Measurement at source level –10 dBm ZVM frq. Harmonic: 10 MHz 20 MHz 30 MHz 30 30 ___________ ___________ 200 MHz 300 MHz 30 30 ___________ ___________ 1000 MHz 1500 MHz 30 30 ___________ ___________ 2 GHz 3 GHz 30 30 ___________ ___________ 3 GHz 4.5 GHz 30 30 ___________ ___________ 1.998 GHz 3.996 GHz 5.
Performance Test Record (ZVM) ZVx Specification min. value/dBc Measured value/dBc 20 MHz 30 MHz 30 30 ___________ ___________ 200 MHz 300 MHz 30 30 ___________ ___________ 1000 MHz 1500 MHz 30 30 ___________ ___________ 2 GHz 3 GHz 30 30 ___________ ___________ 3 GHz 4.5 GHz 30 30 ___________ ___________ 1.998 GHz 3.996 GHz 5.994 GHz 30 30 ___________ ___________ 2 GHz 4 GHz 6 GHz 30 30 ___________ ___________ 5 GHz 7.5 GHz 30 30 ___________ ___________ 5.6 GHz 8.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 3 Spurious 5.2.1.3 Specification min. value/dBc Measured value/dBc Uncertainty / dB Measurement at source level –20 dBm 1127.8500.60 ZVM frq. Spurious: 10 MHz 53.125 MHz 43.125 MHz 35 35 ___________ ___________ 1.4 1.5 50 MHz 202.5 MHz 152.5 MHz 35 35 ___________ ___________ 1.3 1.3 100 MHz 152.5 MHz 52.5 MHz 35 35 ___________ ___________ 1.3 1.3 149 MHz 103.5 MHz 45.
Performance Test Record (ZVM) Item Characteristic 3 1127.8500.60 Measurement acc. to section ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB 5.2.1.3 3.4 GHz 1.7 GHz 5.1 GHz 35 35 ___________ ___________ 1.6 2.0 3.6 GHz 1.8 GHz 5.4 GHz 35 35 ___________ ___________ 1.7 2.1 3.8 GHz 1.9 GHz 5.7 GHz 35 35 ___________ ___________ 1.7 2.1 4.0 GHz 2.0 GHz 6.0 GHz 35 35 ___________ ___________ 1.7 2.1 5 GHz 1.250 GHz 2.500 GHz 3.750 GHz 6.250 GHz 7.500 GHz 8.
ZVx Item Performance Test Record (ZVM) Characteristic 3 1127.8500.60 Measurement acc. to section Specification min. value/dBc Measured value/dBc Uncertainty / dB 5.2.1.3 8 GHz 1.00 GHz 2.00 GHz 3.00 GHz 4.00 GHz 5.00 GHz 6.00 GHz 7.00 GHz 9.00 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.
Performance Test Record (ZVM) Item Characteristic Specification min. value/dBc Measured value/dBc Uncertainty / dB 5.2.1.3 3 1127.8500.60 Measurement acc. to section ZVx 13.8 GHz 1.7250 GHz 3.4500 GHz 5.1750 GHz 6.9000 GHz 8.6250 GHz 10.350 GHz 12.075 GHz 15.525 GHz 17.250 GHz 18.975 GHz 35 35 35 35 35 35 35 35 35 35 ___________ ___________ ___________ ___________ ___________ ___________ ___________ ___________ ___________ ___________ 2.6 2.8 2.9 2.9 3.6 3.6 3.6 3.6 3.6 4.0 15.8 GHz 1.
ZVx Item Performance Test Record (ZVM) Characteristic 3 1.250 GHz 2.500 GHz 3.750 GHz 5.000 GHz 6.250 GHz 7.500 GHz 8.750 GHz 10.00 GHz 11.25 GHz 12.50 GHz 13.75 GHz 15.00 GHz 16.25 GHz 17.50 GHz 18.75 GHz SSB phase noise 0.010 GHz 0.100 GHz 0.500 GHz 1.000 GHz 1.500 GHz 1.998 GHz 2.000 GHz 2.500 GHz 2.800 GHz 3.200 GHz 3.800 GHz 5.000 GHz 5.100 GHz 5.500 GHz 6.000 GHz 6.500 GHz 7.000 GHz 8.000 GHz 10.00 GHz 10.20 GHz 12.00 GHz 13.00 GHz 15.00 GHz 20.00 GHz 1127.8500.60 Specification min.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 5 Residual FM 5.2.1.5 ZVx 0.010 GHz 0.100 GHz 0.500 GHz 1.000 GHz 1.500 GHz 1.998 GHz 2.000 GHz 2.500 GHz 2.800 GHz 3.200 GHz 3.800 GHz 5.000 GHz 5.100 GHz 5.500 GHz 6.000 GHz 6.500 GHz 7.000 GHz 8.000 GHz 10.00 GHz 10.20 GHz 12.00 GHz 13.00 GHz 15.00 GHz 20.00 GHz 1127.8500.60 5.28 Measured value/Hz Specification max.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 6 Level accuracy PORT1 5.2.1.6 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 6 Level accuracy PORT2 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.
Performance Test Record (ZVM) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.0101 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.0 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ ___________ 16.0 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 0.051 f = 0.100 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.0 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ ___________ 16.0 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 0.051 f = 0.
ZVx Performance Test Record (ZVM) Measured value/dB f = 10.000 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.6 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ ___________ 15.4 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 0.051 f = 10.200 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.6 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ ___________ 15.4 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 0.051 f = 12.000 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.6 9.6 4.6 -5.4 –10.
Performance Test Record (ZVM) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.0101 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.0 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ ___________ 16.0 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 0.051 f = 0.100 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.0 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ ___________ 16.0 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 0.051 f = 0.
ZVx Performance Test Record (ZVM) Measured value/dB f = 10.000 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.6 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ ___________ 15.4 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 0.051 f = 10.200 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.6 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ ___________ 15.4 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 0.051 f = 12.000 GHz 15 dB 10 dB 5 dB -5 dB -10 dB 14.6 9.6 4.6 -5.4 –10.
Performance Test Record (ZVM) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.0101 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 12.0 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ ___________ 13.0 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 0.051 f = 0.100 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 12.0 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ ___________ 13.0 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 0.051 f = 0.
ZVx Performance Test Record (ZVM) Measured value/dB f = 10.000 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 11.6 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ ___________ 12.4 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 0.051 f = 10.200 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 11.6 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ ___________ 12.4 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 0.051 f = 12.000 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 11.6 9.6 4.6 -5.4 –10.
Performance Test Record (ZVM) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.0101 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 12.0 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ ___________ 13.0 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 0.051 f = 0.100 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 12.0 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ ___________ 13.0 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 0.051 f = 0.
ZVx Performance Test Record (ZVM) Measured value/dB f = 10.000 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 11.6 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ ___________ 12.4 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 0.051 f = 10.200 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 11.6 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ ___________ 12.4 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 0.051 f = 12.000 GHz 12 dB 10 dB 5 dB -5 dB -10 dB 11.6 9.6 4.6 -5.4 –10.
Performance Test Record (ZVM) Item Characteristic 9 Absolute accuracy PORT1 Measurement acc. to section ZVx Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.
ZVx Performance Test Record (ZVM) Item Characteristic 9 Absolute accuracy PORT2 Measurement acc. to section Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.
Performance Test Record (ZVM) Item Characteristic 9 Absolute accuracy INPUT B1 Measurement acc. to section ZVx Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.
ZVx Performance Test Record (ZVM) Item Characteristic 9 Absolute accuracy INPUT B2 Measurement acc. to section Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.
Performance Test Record (ZVM) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.0101 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 0.058 f = 0.500 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.1 -0.1 -0.1 ___________ ___________ ___________ ___________ ___________ 0.2 0.2 0.1 0.1 0.1 0.058 0.058 0.029 0.029 0.029 f = 1.
ZVx Performance Test Record (ZVM) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 10.20 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 0.058 f = 16.00 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 0.058 f = 20.
Performance Test Record (ZVM) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 0.0101 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 -2 ___________ ___________ ___________ ___________ ___________ 2 2 2 2 2 0.58 0.58 0.58 0.58 0.58 f = 0.500 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -2 -2 -1 -1 -1 ___________ ___________ ___________ ___________ ___________ 2 2 1 1 1 0.58 0.58 0.29 0.29 0.29 f = 1.
ZVx Performance Test Record (ZVM) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 10.20 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 -2 ___________ ___________ ___________ ___________ ___________ 2 2 2 2 2 0.58 0.58 0.58 0.58 0.58 f = 16.00 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 -2 ___________ ___________ ___________ ___________ ___________ 2 2 2 2 2 0.58 0.58 0.58 0.58 0.58 f = 20.
Performance Test Record (ZVM) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.0101 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 0.058 f = 0.500 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.1 -0.1 -0.1 ___________ ___________ ___________ ___________ ___________ 0.2 0.2 0.1 0.1 0.1 0.058 0.058 0.029 0.029 0.029 f = 1.
ZVx Performance Test Record (ZVM) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 10.20 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 0.058 f = 16.00 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 0.058 f = 20.
Performance Test Record (ZVM) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 0.0101 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 -2 ___________ ___________ ___________ ___________ ___________ 2 2 2 2 2 0.58 0.58 0.58 0.58 0.58 f = 0.500 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -2 -2 -1 -1 -1 ___________ ___________ ___________ ___________ ___________ 2 2 1 1 1 0.58 0.58 0.29 0.29 0.29 f = 1.
ZVx Performance Test Record (ZVM) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 10.20 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 -2 ___________ ___________ ___________ ___________ ___________ 2 2 2 2 2 0.58 0.58 0.58 0.58 0.58 f = 16.00 GHz 15 dB 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 -2 ___________ ___________ ___________ ___________ ___________ 2 2 2 2 2 0.58 0.58 0.58 0.58 0.58 f = 20.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 11 Noise level PORT1 5.2.2.3 ZVx Specification min. value/dB Measured value/dB Specification max.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 11 Noise level PORT2 5.2.2.3 Specification min. value/dB Measured value/dB Specification max.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 12 Match INPUT B1 5.2.2.4 ZVx Specification min. value/dB Measured value/dB 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 12 Match INPUT B2 5.2.2.4 Specification min. value/dB Measured value/dB 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.0 10.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 13 Match PORT 1 5.2.3.1 0.010 GHz 0.050 GHz 0.100 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 1127.8500.60 ZVx Specification min. value/dB Measured value/dB 10.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 10.0 10.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 13 Match PORT 2 5.2.3.1 0.010 GHz 0.050 GHz 0.100 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 1127.8500.60 Specification min. value/dB Measured value/dB 10.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 10.0 10.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 14 Match R1 CHANNEL IN 5.2.3.2 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 1127.8500.60 ZVx Specification min. value/dB Measured value/dB 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 14 Match R2 CHANNEL IN 5.2.3.2 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 1127.8500.60 Specification min. value/dB Measured value/dB 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 15 Raw directivity PORT1 5.2.3.3 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 1127.8500.60 ZVx Specification min. value/dB Measured value/dB 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 15 Raw directivity PORT2 5.2.3.3 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 1127.8500.60 Specification min. value/dB Measured value/dB 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 16 Generator step attenuator A1 5.2.3.4 ZVx Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ 3.0 0.2 3.0 3.0 3.0 3.0 3.0 3.0 1.0 Reference 1.0 1.0 1.0 1.0 1.0 1.0 -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 16 Generator step attenuator A2 5.2.3.4 Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ 3.0 0.2 3.0 3.0 3.0 3.0 3.0 3.0 1.0 Reference 1.0 1.0 1.0 1.0 1.0 1.0 -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 16 Receiver step attenuator B1 5.2.3.4 ZVx Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ 3.0 0.2 3.0 3.0 3.0 3.0 3.0 3.0 1.0 Reference 1.0 1.0 1.0 1.0 1.0 1.0 -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 16 Receiver step attenuator B2 5.2.3.4 Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ 3.0 0.2 3.0 3.0 3.0 3.0 3.0 3.0 1.0 Reference 1.0 1.0 1.0 1.0 1.0 1.0 -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 1 5.2.3.5 ZVx Specification min. value/dB Measured value/dB 75.0 75.0 115.0 115.0 115.0 115.0 115.0 115.0 110.0 110.0 110.0 110.0 100.0 100.0 100.0 100.0 100.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ Specification max.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 1 5.2.3.5 Specification min. value/dB Measured value/dB 75.0 75.0 115.0 115.0 115.0 115.0 115.0 115.0 110.0 105.0 105.0 105.0 100.0 100.0 100.0 100.0 100.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ Specification max.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 1 5.2.3.5 ZVx Specification min. value/dB Measured value/dB 45.0 45.0 85.0 85.0 85.0 85.0 85.0 85.0 80.0 80.0 80.0 80.0 70.0 70.0 70.0 70.0 70.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ Specification max.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 2 5.2.3.5 Specification min. value/dB Measured value/dB 75.0 75.0 115.0 115.0 115.0 115.0 115.0 115.0 110.0 110.0 110.0 110.0 100.0 100.0 100.0 100.0 100.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ Specification max.
Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 2 5.2.3.5 ZVx Specification min. value/dB Measured value/dB 75.0 75.0 115.0 115.0 115.0 115.0 115.0 115.0 110.0 105.0 105.0 105.0 100.0 100.0 100.0 100.0 100.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ Specification max.
ZVx Performance Test Record (ZVM) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 2 5.2.3.5 Specification min. value/dB Measured value/dB 45.0 45.0 85.0 85.0 85.0 85.0 85.0 85.0 80.0 80.0 80.0 80.0 70.0 70.0 70.0 70.0 70.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ Specification max.
Performance Test Record (ZVK) 5.4 ZVx Performance Test Record (ZVK) The indicated uncertainties refer to the proposed test setup / test procedure. The expanded measurement uncertainty amounts to k = 2 (confidence level of 95%, Gauss distribution). Additional measurement uncertainties, which are within the user’s responsibility, have not been taken into account (e.g. cable attenuation in harmonics measurements).
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 2 Harmonics PORT1 5.2.1.2 Specification min. value/dBc Measured value/dBc Uncertainty / dB 20 20 ___________ ___________ 1.5 1.5 20 20 ___________ ___________ 1.3 1.3 20 20 ___________ ___________ 1.3 1.3 20 20 ___________ ___________ 1.2 1.6 20 20 ___________ ___________ 1.6 1.7 20 20 ___________ ___________ 1.7 1.7 20 20 ___________ ___________ 1.7 1.7 20 20 ___________ ___________ 2.0 2.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 2 Harmonics PORT1 5.2.1.2 ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB 15 15 ___________ ___________ 4.1 4.5 15 15 ___________ ___________ 4.1 4.5 15 ___________ 4.5 15 ___________ 4.5 15 ___________ 4.5 15 ___________ 4.5 15 ___________ 4.5 25 ___________ 4.5 Measurement at source level 0 dBm (-3 dBm with ZVK-B21) ZVK frq. Harmonic: 10.2 GHz 20.4 GHz 30.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 2 Harmonics PORT2 5.2.1.2 Specification min. value/dBc Measured value/dBc Uncertainty / dB 20 20 ___________ ___________ 1.5 1.5 20 20 ___________ ___________ 1.3 1.3 20 20 ___________ ___________ 1.3 1.3 20 20 ___________ ___________ 1.2 1.6 20 20 ___________ ___________ 1.6 1.7 20 20 ___________ ___________ 1.7 1.7 20 20 ___________ ___________ 1.7 1.7 20 20 ___________ ___________ 2.0 2.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 2 Harmonics PORT2 5.2.1.2 ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB 15 15 ___________ ___________ 4.1 4.5 15 15 ___________ ___________ 4.1 4.5 15 ___________ 4.5 15 ___________ 4.5 15 ___________ 4.5 15 ___________ 4.5 15 ___________ 4.5 25 ___________ 4.5 Measurement at source level 0 dBm (-3 dBm with ZVK-B21) ZVK frq. Harmonic: 10.2 GHz 20.4 GHz 30.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 2 Harmonics PORT1 5.2.1.2 Specification min. value/dBc Measured value/dBc Uncertainty / dB 30 30 ___________ ___________ 1.5 1.5 30 30 ___________ ___________ 1.3 1.3 30 30 ___________ ___________ 1.3 1.3 30 30 ___________ ___________ 1.2 1.6 30 30 ___________ ___________ 1.6 1.7 30 30 ___________ ___________ 1.7 1.7 30 30 ___________ ___________ 1.7 1.7 30 30 ___________ ___________ 2.0 2.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 2 Harmonics PORT1 5.2.1.2 ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB 25 25 ___________ ___________ 4.1 4.5 25 25 ___________ ___________ 4.1 4.5 25 ___________ 4.5 25 ___________ 4.5 25 ___________ 4.5 25 ___________ 4.5 25 ___________ 4.5 25 ___________ 4.5 Measurement at source level –10 dBm ZVK frq. Harmonic: 10.2 GHz 20.4 GHz 30.6 GHz 12 GHz 1127.8500.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 2 Harmonics PORT2 5.2.1.2 Specification min. value/dBc Measured value/dBc Uncertainty / dB 30 30 ___________ ___________ 1.5 1.5 30 30 ___________ ___________ 1.3 1.3 30 30 ___________ ___________ 1.3 1.3 30 30 ___________ ___________ 1.2 1.6 30 30 ___________ ___________ 1.6 1.7 30 30 ___________ ___________ 1.7 1.7 30 30 ___________ ___________ 1.7 1.7 30 30 ___________ ___________ 2.0 2.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 2 Harmonics PORT2 5.2.1.2 ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB 25 25 ___________ ___________ 4.1 4.5 25 25 ___________ ___________ 4.1 4.5 25 ___________ 4.5 25 ___________ 4.5 25 ___________ 4.5 25 ___________ 4.5 25 ___________ 4.5 25 ___________ 4.5 Measurement at source level –10 dBm ZVK frq. Harmonic: 10.2 GHz 20.4 GHz 30.6 GHz 12 GHz 1127.8500.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 3 Spurious 5.2.1.3 Specification min. value/dBc Measured value/dBc Uncertainty / dB Measurement at source level –20 dBm 1127.8500.60 ZVK frq. Spurious: 10 MHz 53.125 MHz 43.125 MHz 35 35 ___________ ___________ 1.4 1.5 50 MHz 202.5 MHz 152.5 MHz 35 35 ___________ ___________ 1.3 1.3 100 MHz 152.5 MHz 52.5 MHz 35 35 ___________ ___________ 1.3 1.3 149 MHz 103.5 MHz 45.
Performance Test Record (ZVK) Item Characteristic 3 1127.8500.60 Measurement acc. to section ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB 5.2.1.3 3.4 GHz 1.7 GHz 5.1 GHz 35 35 ___________ ___________ 1.6 2.0 3.6 GHz 1.8 GHz 5.4 GHz 35 35 ___________ ___________ 1.7 2.0 3.8 GHz 1.9 GHz 5.7 GHz 35 35 ___________ ___________ 1.7 2.1 4.0 GHz 2.0 GHz 6.0 GHz 35 35 ___________ ___________ 1.7 2.1 5 GHz 1.250 GHz 2.500 GHz 3.750 GHz 6.250 GHz 7.500 GHz 8.
ZVx Item Performance Test Record (ZVK) Characteristic 3 1127.8500.60 Measurement acc. to section Specification min. value/dBc Measured value/dBc Uncertainty / dB 5.2.1.3 8 GHz 1.00 GHz 2.00 GHz 3.00 GHz 4.00 GHz 5.00 GHz 6.00 GHz 7.00 GHz 9.00 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.
Performance Test Record (ZVK) Item Characteristic 3 1127.8500.60 Measurement acc. to section ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB 5.2.1.3 13.8 GHz 1.7250 GHz 3.4500 GHz 5.1750 GHz 6.9000 GHz 8.6250 GHz 10.350 GHz 12.075 GHz 15.525 GHz 17.250 GHz 18.975 GHz 20.700 GHz 22.425 GHz 24.150 GHz 25.
ZVx Item Performance Test Record (ZVK) Characteristic 3 Specification min.
Performance Test Record (ZVK) Item Characteristic 3 Specification min.
ZVx Item Performance Test Record (ZVK) Characteristic 3 Specification min.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 4 SSB phase noise 5.2.1.4 0.010 GHz 0.100 GHz 0.500 GHz 1.000 GHz 1.500 GHz 1.998 GHz 2.000 GHz 2.500 GHz 2.800 GHz 3.200 GHz 3.800 GHz 5.000 GHz 5.100 GHz 5.500 GHz 6.000 GHz 6.500 GHz 7.000 GHz 8.000 GHz 10.00 GHz 10.20 GHz 12.00 GHz 13.00 GHz 15.00 GHz 20.00 GHz 20.10 GHz 21.00 GHz 25.00 GHz 26.00 GHz 30.00 GHz 36.00 GHz 40.00 GHz 1127.8500.60 ZVx Specification min. value/dBc Measured value/dBc Uncertainty / dB 100.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 5 Residual FM 5.2.1.5 0.010 GHz 0.100 GHz 0.500 GHz 1.000 GHz 1.500 GHz 1.998 GHz 2.000 GHz 2.500 GHz 2.800 GHz 3.200 GHz 3.800 GHz 5.000 GHz 5.100 GHz 5.500 GHz 6.000 GHz 6.500 GHz 7.000 GHz 8.000 GHz 10.00 GHz 10.20 GHz 12.00 GHz 13.00 GHz 15.00 GHz 20.00 GHz 20.10 GHz 21.00 GHz 25.00 GHz 26.00 GHz 30.00 GHz 36.00 GHz 40.00 GHz 1127.8500.60 5.87 Measured value/Hz Specification max.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 6 Level accuracy Port1 5.2.1.6 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.60 ZVx Specification min.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 6 Level accuracy Port2 5.2.1.6 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.60 Specification min.
Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.010 GHz 10 dB 5 dB -5 dB -10 dB 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 f = 0.100 GHz 10 dB 5 dB -5 dB -10 dB 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 f = 0.150 GHz 10 dB 5 dB -5 dB -10 dB 9.6 4.6 -5.4 –10.
ZVx Performance Test Record (ZVK) Measured value/dB f = 10.200 GHz 10 dB 5 dB -5 dB -10 dB 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 f = 12.000 GHz 10 dB 5 dB -5 dB -10 dB 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 f = 14.000 GHz 10 dB 5 dB -5 dB -10 dB 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.
Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.010 GHz 7 dB 5 dB -5 dB -10 dB 6.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ 8.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 f = 0.100 GHz 7 dB 5 dB -5 dB -10 dB 6.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ 8.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 f = 0.150 GHz 7 dB 5 dB -5 dB -10 dB 6.6 4.6 -5.4 –10.
ZVx Performance Test Record (ZVK) Measured value/dB f = 10.200 GHz 7 dB 5 dB -5 dB -10 dB 6.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 7.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 f = 12.000 GHz 7 dB 5 dB -5 dB -10 dB 6.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 7.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 f = 14.000 GHz 7 dB 5 dB -5 dB -10 dB 6.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 7.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.
Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.010 GHz 10 dB 5 dB -5 dB -10 dB 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 f = 0.100 GHz 10 dB 5 dB -5 dB -10 dB 9.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ 11.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 f = 0.150 GHz 10 dB 5 dB -5 dB -10 dB 9.6 4.6 -5.4 –10.
ZVx Performance Test Record (ZVK) Measured value/dB f = 10.200 GHz 10 dB 5 dB -5 dB -10 dB 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 f = 12.000 GHz 10 dB 5 dB -5 dB -10 dB 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 f = 14.000 GHz 10 dB 5 dB -5 dB -10 dB 9.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 10.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.
Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.010 GHz 7 dB 5 dB -5 dB -10 dB 6.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ 8.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 f = 0.100 GHz 7 dB 5 dB -5 dB -10 dB 6.0 4.0 -6.0 –11.0 ___________ ___________ ___________ ___________ 8.0 6.0 -4.0 –9.0 0.051 0.051 0.051 0.051 f = 0.150 GHz 7 dB 5 dB -5 dB -10 dB 6.6 4.6 -5.4 –10.
ZVx Performance Test Record (ZVK) Measured value/dB f = 10.200 GHz 7 dB 5 dB -5 dB -10 dB 6.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 7.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 f = 12.000 GHz 7 dB 5 dB -5 dB -10 dB 6.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 7.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.051 f = 14.000 GHz 7 dB 5 dB -5 dB -10 dB 6.6 4.6 -5.4 –10.4 ___________ ___________ ___________ ___________ 7.4 5.4 -4.6 –9.6 0.051 0.051 0.051 0.
Performance Test Record (ZVK) Item Characteristic 9 Absolute accuracy PORT1 Measurement acc. to section ZVx Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –3.0 –3.0 –3.0 –3.0 –3.0 –4.0 –4.0 –4.0 –4.
ZVx Performance Test Record (ZVK) Item Characteristic 9 Absolute accuracy PORT2 Measurement acc. to section Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –2.0 –3.0 –3.0 –3.0 –3.0 –3.0 –4.0 –4.0 –4.0 –4.
Performance Test Record (ZVK) Item Characteristic 9 Absolute accuracy INPUT B1 With receiver step attenuator ZVK-B23 installed Input level –10 dBm Difference from –10 dBm: 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 20.10 GHz 21.00 GHz 25.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 35.00 GHz 36.
ZVx Performance Test Record (ZVK) Item Characteristic 9 Absolute accuracy INPUT B2 With receiver step attenuator ZVK-B24 installed Input level –10 dBm Difference from –10 dBm: 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 20.10 GHz 21.00 GHz 25.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 35.
Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.010 GHz 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 f = 0.500 GHz 10 dB 5 dB -5 dB -10 dB -0.2 -0.1 -0.1 -0.1 ___________ ___________ ___________ ___________ 0.2 0.1 0.1 0.1 0.058 0.029 0.029 0.020 f = 1.000 GHz 10 dB 5 dB -5 dB -10 dB -0.2 -0.1 -0.1 -0.
ZVx Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 16.00 GHz 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 f = 20.00 GHz 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 ___________ ___________ ___________ 0.2 0.2 0.2 0.058 0.058 0.058 f = 28.00 GHz 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 ___________ ___________ ___________ 0.2 0.2 0.2 0.058 0.058 0.
Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.010 GHz 7 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 f = 0.500 GHz 7 dB 5 dB -5 dB -10 dB -0.2 -0.1 -0.1 -0.1 ___________ ___________ ___________ ___________ 0.2 0.1 0.1 0.1 0.058 0.029 0.029 0.029 f = 1.000 GHz 7 dB 5 dB -5 dB -10 dB -0.2 -0.1 -0.1 -0.
ZVx Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 16.00 GHz 7 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 f = 20.00 GHz 1 dB -5 dB -10 dB -0.2 -0.2 -0.2 ___________ ___________ ___________ 0.2 0.2 0.2 0.058 0.058 0.058 f = 28.00 GHz 1 dB -5 dB -10 dB -0.2 -0.2 -0.2 ___________ ___________ ___________ 0.2 0.2 0.2 0.058 0.058 0.
Performance Test Record (ZVK) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 0.010 GHz 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 ___________ ___________ ___________ ___________ +2 +2 +2 +2 0.58 0.58 0.58 0.58 f = 0.500 GHz 10 dB 5 dB -5 dB -10 dB -2 -1 -1 -1 ___________ ___________ ___________ ___________ +2 +1 +1 +1 0.58 0.29 0.29 0.29 f = 1.000 GHz 10 dB 5 dB -5 dB -10 dB -2 -1 -1 -1 ___________ ___________ ___________ ___________ +2 +1 +1 +1 0.58 0.
ZVx Performance Test Record (ZVK) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 16.00 GHz 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 ___________ ___________ ___________ ___________ +2 +2 +2 +2 0.58 0.58 0.58 0.58 f = 20.00 GHz 5 dB -5 dB -10 dB -2 -2 -2 ___________ ___________ ___________ +2 +2 +2 0.58 0.58 0.58 f = 28.00 GHz 5 dB -5 dB -10 dB -2 -2 -2 ___________ ___________ ___________ +2 +2 +2 0.58 0.58 0.58 f = 36.
Performance Test Record (ZVK) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 0.010 GHz 7 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 ___________ ___________ ___________ ___________ +2 +2 +2 +2 0.58 0.58 0.58 0.58 f = 0.500 GHz 7 dB 5 dB -5 dB -10 dB -2 -1 -1 -1 ___________ ___________ ___________ ___________ +2 +1 +1 +1 0.58 0.29 0.29 0.29 f = 1.000 GHz 7 dB 5 dB -5 dB -10 dB -2 -1 -1 -1 ___________ ___________ ___________ ___________ +2 +1 +1 +1 0.58 0.
ZVx Performance Test Record (ZVK) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 16.00 GHz 7 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 ___________ ___________ ___________ ___________ +2 +2 +2 +2 0.58 0.58 0.58 0.58 f = 20.00 GHz 1 dB -5 dB -10 dB -2 -2 -2 ___________ ___________ ___________ +2 +2 +2 0.58 0.58 0.58 f = 28.00 GHz 1 dB -5 dB -10 dB -2 -2 -2 ___________ ___________ ___________ +2 +2 +2 0.58 0.58 0.58 f = 36.
Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.010 GHz 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 f = 0.500 GHz 10 dB 5 dB -5 dB -10 dB -0.2 -0.1 -0.1 -0.1 ___________ ___________ ___________ ___________ 0.2 0.1 0.1 0.1 0.058 0.029 0.029 0.020 f = 1.000 GHz 10 dB 5 dB -5 dB -10 dB -0.2 -0.1 -0.1 -0.
ZVx Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 16.00 GHz 10 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 f = 20.00 GHz 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 ___________ ___________ ___________ 0.2 0.2 0.2 0.058 0.058 0.058 f = 28.00 GHz 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 ___________ ___________ ___________ 0.2 0.2 0.2 0.058 0.058 0.
Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 0.010 GHz 7 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 f = 0.500 GHz 7 dB 5 dB -5 dB -10 dB -0.2 -0.1 -0.1 -0.1 ___________ ___________ ___________ ___________ 0.2 0.1 0.1 0.1 0.058 0.029 0.029 0.029 f = 1.000 GHz 7 dB 5 dB -5 dB -10 dB -0.2 -0.1 -0.1 -0.
ZVx Performance Test Record (ZVK) Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB f = 16.00 GHz 7 dB 5 dB -5 dB -10 dB -0.2 -0.2 -0.2 -0.2 ___________ ___________ ___________ ___________ 0.2 0.2 0.2 0.2 0.058 0.058 0.058 0.058 f = 20.00 GHz 1 dB -5 dB -10 dB -0.2 -0.2 -0.2 ___________ ___________ ___________ 0.2 0.2 0.2 0.058 0.058 0.058 f = 28.00 GHz 1 dB -5 dB -10 dB -0.2 -0.2 -0.2 ___________ ___________ ___________ 0.2 0.2 0.2 0.058 0.058 0.
Performance Test Record (ZVK) Item 10 1127.8500.60 ZVx Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 0.010 GHz 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 ___________ ___________ ___________ ___________ +2 +2 +2 +2 0.58 0.58 0.58 0.58 f = 0.500 GHz 10 dB 5 dB -5 dB -10 dB -2 -1 -1 -1 ___________ ___________ ___________ ___________ +2 +1 +1 +1 0.58 0.29 0.29 0.29 f = 1.
ZVx Performance Test Record (ZVK) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 16.00 GHz 10 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 ___________ ___________ ___________ ___________ +2 +2 +2 +2 0.58 0.58 0.58 0.58 f = 20.00 GHz 5 dB -5 dB -10 dB -2 -2 -2 ___________ ___________ ___________ +2 +2 +2 0.58 0.58 0.58 f = 28.00 GHz 5 dB -5 dB -10 dB -2 -2 -2 ___________ ___________ ___________ +2 +2 +2 0.58 0.58 0.58 f = 36.
Performance Test Record (ZVK) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 0.010 GHz 7 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 ___________ ___________ ___________ ___________ +2 +2 +2 +2 0.58 0.58 0.58 0.58 f = 0.500 GHz 7 dB 5 dB -5 dB -10 dB -2 -1 -1 -1 ___________ ___________ ___________ ___________ +2 +1 +1 +1 0.58 0.29 0.29 0.29 f = 1.000 GHz 7 dB 5 dB -5 dB -10 dB -2 -1 -1 -1 ___________ ___________ ___________ ___________ +2 +1 +1 +1 0.58 0.
ZVx Performance Test Record (ZVK) Specification min. value/° Measured value/° Specification max. value/° Uncertainty / ° f = 16.00 GHz 7 dB 5 dB -5 dB -10 dB -2 -2 -2 -2 ___________ ___________ ___________ ___________ +2 +2 +2 +2 0.58 0.58 0.58 0.58 f = 20.00 GHz 1 dB -5 dB -10 dB -2 -2 -2 ___________ ___________ ___________ +2 +2 +2 0.58 0.58 0.58 f = 28.00 GHz 1 dB -5 dB -10 dB -2 -2 -2 ___________ ___________ ___________ +2 +2 +2 0.58 0.58 0.58 f = 36.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 11 Noise level PORT1 5.2.2.3 ZVx Specification min. value/dB Measured value/dB Specification max.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 11 Noise level PORT2 5.2.2.3 Specification min. value/dB Measured value/dB Specification max.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 12 Match INPUT B1 5.2.2.4 ZVx Specification min. value/dB Measured value/dB 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 12 Match INPUT B2 5.2.2.4 Specification min. value/dB Measured value/dB 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 13 Match PORT1 5.2.3.1 0.010 GHz 0.050 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 2.000 GHz 4.000 GHz 6.000 GHz 8.000 GHz 10.00 GHz 12.00 GHz 14.00 GHz 16.00 GHz 16.10 GHz 18.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.60 ZVx Specification min. value/dB Measured value/dB 10.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 10.0 10.0 10.0 10.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 13 Match PORT2 5.2.3.1 0.010 GHz 0.050 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 2.000 GHz 4.000 GHz 6.000 GHz 8.000 GHz 10.00 GHz 12.00 GHz 14.00 GHz 16.00 GHz 16.10 GHz 18.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.60 Specification min. value/dB Measured value/dB 10.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0 10.0 10.0 10.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 14 Match R1 CHANNEL IN 5.2.3.2 0.010 GHz 0.050 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 2.000 GHz 4.000 GHz 6.000 GHz 8.000 GHz 10.00 GHz 12.00 GHz 14.00 GHz 16.00 GHz 16.10 GHz 18.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.60 ZVx Specification min. value/dB Measured value/dB 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 14 Match R2 CHANNEL IN 5.2.3.2 0.010 GHz 0.050 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 2.000 GHz 4.000 GHz 6.000 GHz 8.000 GHz 10.00 GHz 12.00 GHz 14.00 GHz 16.00 GHz 16.10 GHz 18.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.60 Specification min. value/dB Measured value/dB 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.0 8.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 15 Raw directivity PORT1 5.2.3.3 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 15 Raw directivity PORT2 5.2.3.3 0.010 GHz 0.100 GHz 0.150 GHz 0.500 GHz 1.000 GHz 1.500 GHz 2.000 GHz 3.000 GHz 4.000 GHz 5.000 GHz 6.000 GHz 7.000 GHz 8.000 GHz 9.000 GHz 10.00 GHz 11.00 GHz 12.00 GHz 13.00 GHz 14.00 GHz 15.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 16 Generator step attenuator A1 5.2.3.4 ZVx Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ 3.0 0.2 3.0 3.0 3.0 3.0 3.0 3.0 1.0 Reference 1.0 1.0 1.0 1.0 1.0 1.0 -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 16 Generator step attenuator A2 5.2.3.4 Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ 3.0 0.2 3.0 3.0 3.0 3.0 3.0 3.0 1.0 Reference 1.0 1.0 1.0 1.0 1.0 1.0 -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 16 Receiver step attenuator B1 5.2.3.4 ZVx Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ 3.0 0.2 3.0 3.0 3.0 3.0 3.0 3.0 1.0 Reference 1.0 1.0 1.0 1.0 1.0 1.0 -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 16 Receiver step attenuator B2 5.2.3.4 Specification min. value/dB Measured value/dB Specification max. value/dB Uncertainty / dB -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.0 ____________ ____________ ____________ ____________ ____________ ____________ ____________ ____________ 3.0 0.2 3.0 3.0 3.0 3.0 3.0 3.0 1.0 Reference 1.0 1.0 1.0 1.0 1.0 1.0 -3.0 -0.2 -3.0 -3.0 -3.0 -3.0 -3.0 -3.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 1 IF BW 10 Hz: 5.2.3.5 0.010 GHz 0.100 GHz 0.500 GHz 1.000 GHz 2.000 GHz 4.000 GHz 6.000 GHz 8.000 GHz 10.00 GHz 12.00 GHz 14.00 GHz 16.00 GHz 16.10 GHz 17.00 GHz 18.00 GHz 19.00 GHz 20.00 GHz 22.00 GHz 24.00 GHz 26.00 GHz 28.00 GHz 30.00 GHz 32.00 GHz 34.00 GHz 36.00 GHz 38.00 GHz 40.00 GHz 1127.8500.60 ZVx Specification min. value/dB Measured value/dB 70.0 70.0 110.0 110.0 110.0 110.0 110.0 110.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 1 5.2.3.5 Specification min. value/dB Measured value/dB 40.0 40.0 80.0 80.0 80.0 80.0 80.0 80.0 75.0 75.0 75.0 75.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0 50.0 50.0 50.0 50.0 50.0 50.
Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 2 5.2.3.5 ZVx Specification min. value/dB Measured value/dB 70.0 70.0 110.0 110.0 110.0 110.0 110.0 110.0 105.0 105.0 105.0 105.0 90.0 90.0 90.0 90.0 90.0 90.0 90.0 90.0 90.0 80.0 80.0 80.0 80.0 80.0 80.
ZVx Performance Test Record (ZVK) Item Characteristic Measurement acc. to section 17 Dynamic range PORT 2 5.2.3.5 Specification min. value/dB Measured value/dB 40.0 40.0 80.0 80.0 80.0 80.0 80.0 80.0 75.0 75.0 75.0 75.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0 50.0 50.0 50.0 50.0 50.0 50.
ZVx Interfaces Annex A - Interfaces A.1 IEC Bus Interface (SCPI IEC625, SYSTEM BUS) The standard network analyzer is equipped with twp IEC/IEEE bus connectors. The IEEE 488 interface connector is located on the rear panel of the instrument. An external controller for remote control of the networkanalyzer can be connected via the IEEE 488 interface connector using a shielded cable. The third IEC Bus interface is assigned to the MS-DOS processor, with an installed processor option.
Interfaces ZVx Bus Lines 1. Data bus with 8 lines DIO 1 to DIO 8. The transmission is bit-parallel and byte-serial in the ASCII/ISO code. DIO1 is the least significant, DIO8 the most significant bit. 2. Control bus with 5 lines. IFC (Interface Clear), active low resets the interfaces of the devices connected to the default setting. ATN (Attention), active low signals the transmission of interface messages inactive high signals the transmission of device messages.
ZVx Interfaces Interface Functions Instruments which can be remote controlled via the IEC bus can be equipped with different interface functions. Table A-1 lists the interface functions appropriate for the instrument. Table A-1 Interface functions Control character Interface function SH1 Handshake source function (source handshake), full capability AH1 Handshake sink function (acceptor handshake), full capability L4 Listener function, full capability, deaddressed by MTA.
Interfaces ZVx Universal Commands The universal commands are encoded 10 - 1F hex. They affect all instruments connected to the bus without addressing. Table A-2 Universal Commands Command QuickBASIC command Effect on the instrument DCL (Device Clear) IBCMD (controller%, CHR$(20)) Aborts the processing of the commands just received and sets the command processing software to a defined initial state. Does not change the instrument settings.
ZVx Interfaces A.2 RS-232-C Interface (COM1, COM2) The standard instrument is equipped with two serial interfaces (RS-232-C). The RS-232-C interfaces are two independent, remote-control channels, both of which may be active at the same time. The programming and interrogation commands affect the same instrument hardware.
Interfaces ZVx 2. Control lines DCD (Data Carrier Detect), Not used in this instrument. Input; active LOW. Using this signal, the local terminal recognises that the modem of the remote station receives valid signals with sufficient level. DCD is used to disable the receiver in the local terminal and prevent reading of false data if the modem cannot interpret the signals of the remote station. DTR (Data Terminal Ready), Output, active LOW, Indicates that the local terminal is ready to receive data.
ZVx Interfaces Interface Functions For interface control, several strings are defined and control characters are reserved which are based upon IEC Bus control.
Interfaces ZVx Hardware handshake For hardware handshake, the instrument indicates that it is ready to receive data via the lines DTR and RTS. A logic ’0’ on both lines means "ready" and a logic ’1’ means "not ready". The RTS line is always active (logic ’0’) as long as the serial interface is switched on. The DTR line thus controls the readiness of the instrument to receive data. The readiness of the remote station to receive data is reported to the instrument via the CTS and DSR line.
ZVx A.3 Interfaces RSIB Interface The instrument is equipped with an RSIB interface as standard, which enables controlling of the instrument by means of Visual C++ and Visual Basic programs. The control applications run on an external computer in the network. A Unix operating system can be installed on an external computer in addition to a Windows operating system. In this case, the control applications are created either in C or C++. The supported Unix operating systems include: • Sun Solaris 2.
Interfaces ZVx The RSIB directory also contains the program RSIBCNTR.EXE with which SCPI commands can be sent to the instrument via the RSIB interface. This program can be used to test the function of the interface. Required for the test is delay module VBRUN300.DLL in the path or in the Windows directory. The control is performed with Visual C++ or Visual Basic programs. The local link to the internal controller is established with the name ’@local’.
ZVx Interfaces RSIB Interface Functions This chapter lists all functions of the DLL "RSIB.DLL" or "RSIB32.DLL" or "librsib.so", which allow to produce control applications. Variables ibsta, iberr, ibcntl Same as with the National Instruments interface, successful execution of a command can be checked by means of the variables ibsta, iberr and ibcntl. To this end, references to the three variables are transferred to all RSIB functions.
Interfaces ZVx Count variable - ibcntl The variable ibcntl is updated with the number of bytes transmitted on every read and write function call. Overview of Interface Functions The library functions are adapted to the interface functions of National Instruments for GPIB programming. The functions supported by the libraries are listed in the following table. Function Description RSDLLibfind() Provides a handle for access to a device. RSDLLibwrt() Sends a zero-terminated string to a device.
ZVx Interfaces Description of Interface Functions RSDLLibfind() The function provides a handle for access to the device with the name udName.
Interfaces ZVx RSDLLilwrt This function sends Cnt bytes to a device with the handle ud.
ZVx Interfaces RSDLLibrd() The function reads data from the device with the handle ud into the string Rd. VB format: Function RSDLLibrd (ByVal ud%, ByVal Rd$, ibsta%, iberr%, ibcntl&) As Integer C format: short WINAPI RSDLLibrd( short ud, char far *Rd, short far *ibsta, short far *iberr, unsigned long far *ibcntl ) C format (Unix): short RSDLLibrd( short ud, char *Rd, short *ibsta, short *iberr, unsigned long *ibcntl ) Parameter: Example: ud Device handle Rd String into which the read data is copied.
Interfaces ZVx RSDLLibrdf() Reads data from the device with the handle ud into the file file. VB format: Function RSDLLibrdf (ByVal ud%, ByVal file$, ibsta%, iberr%, ibcntl&) As Integer C format: short WINAPI RSDLLibrd( short ud, char far *file, short far *ibsta, short far *iberr, unsigned long far *ibcntl ) C format (Unix): short RSDLLibrd( short ud, char *file, short *ibsta, short *iberr, unsigned long *ibcntl ) Parameter: ud file Device handle File into which the read data is written.
ZVx Interfaces RSDLLibsre This function sets the device to the ’LOCAL’ or ’REMOTE’ state.
Interfaces ZVx RSDLLibrsp This function performs a serial poll and provides the status byte of the device.
ZVx Interfaces RSDLLTestSRQ This function checks the status of the SRQ bit.
Interfaces ZVx RSDLLSwapBytes This function changes the display of binary numbers on non-Intel platforms. VB format: Not provided at present since it is required only on non-Intel platforms.
ZVx Interfaces A.4 User Interface (USER) The user interface, located on the rear panel of the ZVx, is a 25 pin Cannon connector which provides access to the two user ports (Port A and Port B). Each port is 8 bits wide (A0 - A7 and B0 -B7) and can be configured either as output or as input. The voltage levels are TTL levels (Low < 0,4 V, High > 2 V). In addition, an internal +5 V power supply voltage is provided. The maximum load current is 100 mA.
Interfaces A.5 ZVx Printer Interface (LPT) The 25-pin LPT connector on the rear panel of the ZVx is provided for the connection of a printer. The LPT interface is compatible with the CENTRONICS printer interface. PE ACK SELECT BUSY D4 D6 D7 D5 D2 D0 D1 D3 STROBE 13 1 25 14 GND GND INIT AUTOFEED GND GND GND GND GND GND ERROR SELECT IN Pin Signal Input (I) Output (O) Description 1 STROBE O Pulse for transmitting a data byte, min.
ZVx A.6 Interfaces Probe Connectors (PROBE 1, PROBE 2) To allow the connection of probes, the ZVx has the supply voltage connectors PROBE 1 and PROBE 2. They deliver the power supply voltages +15 V, -12 V and ground. The connectors are also suited for powering the high-impedance probes from Hewlett Packard. A.7 Reference Input (REF IN) A high-precision external reference oscillator, used to increase the frequency accuracy and to improve the stability of the internal reference, can be connected here.
Interfaces A.12 ZVx Connectors for Controlling an External Generator of the R&S Family SME / SMP and other (BLANK, TRIGGER) A special feature for of the signal generators of the Rohde & Schwarz SME and SMP families is the socalled "list mode" which serves to accelerate the sweep in the case of external control. In this mode a list containing a series of frequency points with the corresponding level is transmitted to the generator, e.g. via IEC-bus.
ZVx Interfaces A.15 Mouse Connector (MOUSE) 6 1 5 2 4 3 Pin Signal 1 MOUSEDATA 2 NC 3 MOUSEGND 4 MOUSEVD5 5 MOUSECLK 6 NC Fig A-8 Pin assignments for the MOUSE connector. A.16 Monitor Connectors (PC MONITOR, ANALYZER MONITOR) 1 5 10 6 11 15 Pin Signal 1 R 2 G 3 B 4 MID2 5 NC 6 R-GND 7 G-GND 8 B-GND 9 NC 10 GND 11 MID0 12 MID1 13 HSYNC 14 VSYNC 15 NC Fig. A-9 1043.0009.50 Pin assignments of the MONITOR connector. A.
ZVx List of Error Messages Annex B – List of Error Messages The following list contains all error messages for errors occurring in the instrument. The meaning of negative error codes is defined in SCPI, positive error codes mark errors specific of the instrument. The table contains the error code in the left-hand column. In the right-hand column the error text being entered into the error/event queue or being displayed is printed in bold face.
List of Error Messages ZVx Continuation: Command Error Error code Error text in the case of queue poll Error explanation -109 Missing parameter The command contains too few parameters. Example: The command SENSe:FREQuency:CENTer requires a frequency indication. -110 Command header error The header of the command is faulty. -111 Header separator error The header contains an impermissible separator.
ZVx List of Error Messages Continuation: Command Error Error code Error text in the case of queue poll Error explanation -144 Character data too long The text parameter contains more than 12 characters. -148 Character data not allowed The text parameter is not allowed for this command or at this position of the command. Example: The command *RCL requires a number to be indicated. -150 String data error The command contains a faulty string.
List of Error Messages ZVx Execution Error - Error on execution of a command; sets bit 4 in the ESR register Error code Error text in the case of queue poll Error explanation -200 Execution error Error on execution of the command. -201 Invalid while in local The command is not executable while the device is in local due to a hard local control. Example: The device receives a command which would change the rotary knob state, but the device is in local so the command can not be executed.
ZVx List of Error Messages Continuation: Execution Error Error code Error text in the case of queue poll Error explanation -230 Data corrupt or stale The data are incomplete or invalid. Example: The instrument has aborted a measurement. -231 Data questionable The measurement accuracy is suspect. -240 Hardware error The command cannot be executed due to problems with the instrument hardware. -241 Hardware missing Hardware is missing. Example: An option is not fitted.
List of Error Messages ZVx Continuation: Execution Error Error code Error text in the case of queue poll Error explanation -270 Macro error Error on the execution of a macro. -271 Macro syntax error The macro definition contains a syntax error. -272 Macro execution error The macro definition contains an error. -273 illegal macro label An illegal macro label is defined in the *DMC command. Example: The label is too long.
ZVx List of Error Messages Device Specific Error; sets bit 3 in the ESR register Error code Error test in the case of queue poll Error explanation -300 Device-specific error FSE-specific error not defined in greater detail. -310 System error This error message suggests an error within the instrument. Please inform the R&S Service. -311 Memory error Error in the instrument memory. -312 PUD memory lost Loss of the protected user data stored using the *PUD command.
ZVx List of Commands Annex C – List of Commands Command Parameters Page CALCulate[1...4]: FILTer[:GATE]:TIME:STARt 3.20 CALCulate[1...4]: FILTer[:GATE]:TIME:STATe 3.20 CALCulate[1...4]:FILTer[:GATE]:TIME:CENTer 3.21 CALCulate[1...4]:FILTer[:GATE]:TIME:DCHebyshev 3.21 CALCulate[1...4]:FILTer[:GATE]:TIME:SPAN 3.21 CALCulate[1...4]:FILTer[:GATE]:TIME:STOP 3.20 CALCulate[1...
List of Commands ZVx Command Parameters Page CALCulate[1...4]:MARKer[1...8]:FUNCtion:DELTa:REFerence: RPOSition:POLar ,, 3.35 CALCulate[1...4]:MARKer[1...8]:FUNCtion:DELTa:STATe ON | OFF 3.35 CALCulate[1...4]:MARKer[1...8]:FUNCtion:PTPeak:RESult? 3.36 CALCulate[1...4]:MARKer[1...8]:FUNCtion:QFACtor 3.34 CALCulate[1...4]:MARKer[1...8]:FUNCtion:REFerence – CALCulate[1...4]:MARKer[1...8]:FUNCtion:RESULT? CALCulate[1...4]:MARKer[1...
ZVx List of Commands Command CALCulate[1...4]:TRANSform:TIME:XAXis Parameters TIME | DISTance | HDIStance Page 3.42 CALCulate[1...4]:TRANsform:TIME[:TYPE] BPASs | LPASs 3.41 CALCulate[1...4]:UNIT:POWer:A1|A2|B1|B2 MW | W | UV | MV | V | DBM | DBW | DBUV | DBMV | DBV 3.43 DIAGnostic:SERVice:FUNCtion ,... 3.44 DIAGnostic:SERVice:RFPower ON | OFF 3.44 DISPlay:FORmat SINGle | DOVerlay | QOVerlay | DSPLit | QDSPlit | QQSPlit 3.
List of Commands ZVx Command Parameters Page HCOPy:ITEM:PFEed[1|2]:STATe ON | OFF 3.58 HCOPy:ITEM:WINDow[1...4]:TRACe[1|2]:LTYPe SOLid | STYLe 3.59 HCOPy:ITEM:WINDow[1...4]:TRACe[1|2]:LTYPe:AINCrement ON | OFF 3.60 HCOPy:ITEM:WINDow[1...4]:TRACe[1|2]:LTYPe:STATe ON | OFF 3.59 HCOPy:ITEM:WINDow<1|2>:TABLe:STATe ON | OFF 3.58 HCOPy:ITEM:WINDow<1|2>:TEXT 3.59 HCOPy:ITEM:WINDow<1|2>:TRACe:CAINcrement ON | OFF 3.
ZVx List of Commands Command Parameters Page MMEMory:SELect[:ITEM]:HWSettings ON|OFF 3.69 MMEMory:SELect[:ITEM]:LINes[:ALL] ON|OFF 3.69 MMEMory:SELect[:ITEM]:MACRos ON|OFF 3.70 MMEMory:SELect[:ITEM]:MTRace<1...8> ON|OFF 3.69 MMEMory:SELect[:ITEM]:NONE 3.71 MMEMory:STORe:STATe 1, path 3.68 OUTPut:DPORt PORT1 | PORT2 3.72 OUTPut[1|2]:POWer NORMal | HIGH 3.72 OUTPut:RMIXer ON | OFF 3.72 OUTPut:UPORt<1|2>:STATe ON | OFF 3.73 OUTPut:UPORt<1|2>[:VALue] binary data 3.
List of Commands ZVx Command Parameters Page [SENSe[1...4]:]CORRection:CKIT:PC[7|35] MMTHrough | MFTHrough | FFTHrough | MMLINE1 | FLINE1 | FFLINE1 | MMLINE2 | MFLINE2 | FFLINE2 | MMATten | MFATten | FFATten | MMSNetwork | MFSNetwork | FFSNetwork | MOPEn | FOPEn | MSHort | FSHort | MREFlect | FREFlect | MMATch | FMATch | MSMatch | FSMatch[,] 3.96 [SENSe[1...
ZVx List of Commands Command Parameters Page [SENSe[1...4]:]FREQuency:NLINear:COMP:STIMe 3.106 [SENSe[1...4]:]FREQuency:NLINear:SOI:STIMe 3.106 [SENSe[1...4]:]FREQuency:NLINear:TOI:STIMe 3.106 [SENSe[1...4]:]FREQuency:SPAN 3.103 [SENSe[1...4]:]FREQuency:STARt 3.103 [SENSe[1...4]:]FREQuency:STOP 3.103 [SENSe[1...4]:]FUNCtion[:ON] 3.107 [SENSe[1...4]:]SEGMent: CLEar 3.
List of Commands ZVx Command Parameters Page SOURce<1...4>:POWer:CORRection:LLISt ,, ... 3.120 SOURce<1...4>:POWer:CORRection:LLISt:STATe ON | OFF 3.121 SOURce<1...4>:POWer:CORRection:NREadings . 3.120 SOURce<1...4>:POWer:CORRection[:ACQuire] A1 | A2 | ESRC1 | ESRC2 3.120 SOURce<1...4>:POWer:STARt 3.119 SOURce<1...4>:POWer:STOP 3.119 SOURce<1...
ZVx List of Commands Command Parameters Page SYSTem:COMMunicate:GPIB:RDEVice:PMETer:ADDRess 0...30 SYSTem:COMMunicate:GPIB:RDEVice<1|2>:ADDRess 0...30 3.131 SYSTem:COMMunicate:GPIB[:SELF]:ADDRess 0...30 3.131 SYSTem:COMMunicate:GPIB[:SELF]:RTERminator LFEOI | EOI SYSTem:COMMunicate:PRINter<1|2>:ENUMerate:FIRSt? 3.132 3.131 3.132 SYSTem:COMMunicate:PRINter<1|2>:ENUMerate:NEXT? 3.132 SYSTem:COMMunicate:PRINter<1|2>:SELect 3.
List of Commands ZVx Command Parameters Page TRACe[:DATA]:STIMulus:BODY? CH1DATA | CH2DATA | CH3DATA |CH4DATA | CH1MEM | CH2MEM | CH3MEM | CH4MEM | MDATA1 | MDATA2 | MDATA3 | MDATA4 | MDATA5 | MDATA6 | MDATA7 | MDATA8 3.142 TRACe[:DATA]:STIMulus:PREamble? CH1DATA | CH2DATA | CH3DATA |CH4DATA | CH1MEM | CH2MEM | CH3MEM | CH4MEM | MDATA1 | MDATA2 | MDATA3 | MDATA4 | MDATA5 | MDATA6 | MDATA7 | MDATA8 3.
ZVx Programming Examples Annex D – Programming Examples The following examples explain the programming of the instrument and can serve as a basis to solve more complex programming tasks. QuickBASIC has been used as programming language. However, the programs can be translated into other languages. D.1 Including IEC-Bus Library for QuickBasic REM --- Include IEC-bus library for quickbasic -.Example for path definition ’$INCLUDE: ’c:\qbasic\qbdecl4.bas’ D.
Programming Examples D.3 ZVx Transmission of Instrument Setting Commands Center frequency, span, and reference level of the analyzer are set in this example. REM -------- Instrument setting commands ------------CALL IBWRT(analyzer%, "FREQUENCY:CENTER 120MHz") ’Center frequency 120 MHz CALL IBWRT(analyzer%, "FREQUENCY:SPAN 10MHZ") ’Span 10 MHz CALL IBWRT(analyzer%, "DISPLAY:TRACE:Y:SPACING LINear") ’Linear scaling REM *********************************************************************** D.
ZVx D.7 Programming Examples Command synchronization The possibilities for synchronization implemented in the following example are described in Section 3.7.6, Command Order and Command Synchronization. REM REM REM REM -------- Examples of command synchronization --------The command INITiate[:IMMediate] starts a single sweep if the command INIT:CONT OFF was previously sent. It should be ensured that the next command is only then executed when the entire sweep is complete.
Programming Examples D.8 ZVx Service Request The service request routine requires an extended initialization of the instrument in which the respective bits of the transition and enable registers are set.
ZVx Programming Examples Reading out the status event registers, the output buffer and the error/event queue is effected in subroutines.
Programming Examples D.9 ZVx Programming via the RSIB Interface The following hints apply to both the 16-bit and the 32-bit DLL versions (RSIB.DLL and RSIB32.DLL) unless an explicit distinction is made. The RSIB interface supports links to max. 16 measuring instruments at the same time. D.9.1 Visual Basic Programming hints: • Access to the functions of the RSIB.DLL To create Visual Basic control applications, the file RSIB.BAS must be added to a project for 16-bit Basic programs and the file RSIB32.
ZVx Programming Examples Example: Dim Dim Dim Dim Dim Dim Dim Dim ibsta As Integer iberr As Integer ibcntl As Long ud As Integer Result As String Digits As Byte TraceBytes As Long TraceData(401) As Single ’ ’ ’ ’ ’ ’ ’ ’ ’ Status variable Error variable Count variable Handle for measuring instrument Buffer for simple results Number of digits of length indication Length of trace data in bytes Buffer for floating point Binary data ’ Set up connection to instrument ud = RSDLLibfind("89.10.38.
Programming Examples ZVx • In this example, a Save/Recall of the instrument setups is performed. Dim Dim Dim Dim Dim ibsta As Integer iberr As Integer ibcntl As Long ud As Integer Cmd As String ’ ’ ’ ’ ’ Status variable Error variable Count variable Handle for measuring instrument Command string ’ Set up connection to measuring instrument ud = RSDLLibfind("89.10.38.
ZVx Programming Examples Programming example: • Using the macro QueryMaxPeak a single sweep with subsequent query of the maximum peak is performed. The result is entered in a Winword or Excel document.
Programming Examples D.9.3 ZVx C / C++ Programming hints: • Access to the functions of the RSIB32.DLL (Windows platforms) The functions of the RSIB32.DLL are declared in the header file RSIB.H. The DLL functions can be linked to a C/C++ program in different ways. 1. Enter one of the supplied import libraries (RSIB.LIB or RSIB32.LIB) into the linker options. 2. Load the library using the function LoadLibrary() during runtime and determine the function pointers of the DLL functions using GetProcAddress().
ZVx Programming Examples Programming example: In the following C program example, a single sweep is started on the device with the IP address 89.10.38.97 and subsequently a marker is set to maximum level. Prior to the search for maximum, a synchronization to the end of the sweep is performed. For this purpose the command "*OPC" (Operation complete) is used to create a service request at the end of the sweep, for which the control program waits with the function RSDLLWaitSrq().
ZVx Mouse Control Annex E - Emulations E.1 Mouse Control of Display Elements The network analyzer can be optionally equipped with a mouse (see Chapter 1 "Connecting a Mouse"). All display and control elements (enhancement labels, softkeys, function fields, display and limit lines) which can be displayed on the display screen can also be controlled by the mouse. Each softkey or key is assigned to a display element.
External Keyboard E.2 ZVx Front Panel Keyboard Emulation The network analyzer can be equipped with an optional external keyboard (see Chapter 1 "Connecting an External Keyboard"). The following table shows the external keyboard key combinations through which the functions of the front panel keys can be emulated. In addition, the keys which are only available on the external keyboard are shown.