A73x addWAVE User Guide valid for A731, A732, A733 and A733GSM RTUs Release 2.0 and higher Rel. 2.
ADCON TELEMETRY GmbH INKUSTRASSE 24 A-3400 KLOSTERNEUBURG A U S T R I A TEL: +43-2243-38280-0 FAX: +43-2243-38280-6 http://www.adcon.at Proprietary Notice: The Adcon logo, the A720 series and addIT™, the A730 series and addWAVE, addVANTAGE and AgroExpert™ are trademarks or registered trademarks of Adcon Telemetry GmbH. All other registered names used throughout this publication are trademarks of their respective owners. This publication contains confidential information, property of Adcon Telemetry GmbH.
Table of Contents Table of Contents 1 Introduction ......................................................................... 5 1.1 About the addWAVE A73x...............................................................5 1.2 Compliance Statement and Warnings .............................................6 1.3 Conventions .....................................................................................7 2 Using the A73x RTU ............................................................ 9 2.
Table of Contents FREQ .............................................................................................23 RSSI...............................................................................................24 ID....................................................................................................24 SLOT..............................................................................................25 SST ................................................................................
Introduction 1 Introduction This manual explains the hardware aspects of Adcon’s A733, A732, A731 and A733GSM remote telemetry units (further referred to as A73x), including installation issues and certain parameter configurations. The manual is divided as follows: 1.1 • "Introduction", which gives some general information and document conventions. • "Using the A73x RTU", which details the installation and use of the remote telemetry unit.
Compliance Statement and Warnings supports the SDI-12 bus implementation. The unit is based on a powerful 8 bit Flash RISC microcontroller, that can also be field programmed (software upgraded). The only difference between these devices and the A732 and A731 is the number of analog and digital interfaces. The A731, A732 and A733 RTUs incorporate an A431 radio module operating in the 430 to 470 MHz range, making it adaptable to most radio communication regulations in the world.
Introduction This device complies with Part 15 of the FCC Rules. Operation is subject to the following conditions: 1. this device may not cause harmful interference, 2. this device must accept any interference received, including interference that may cause undesired operation, 3. any manipulations on this device other than mentioned in this manual void the FCC type approval. 1.3 Conventions Certain conventions apply in this documentation.
Using the A73x RTU 2 Using the A73x RTU The A73x series of remote telemetry units (RTU) is part of the A730 series. For testing purposes, you should have an A730SD/A730MD and/or an A840 Telemetry Gateway installed before you install your A73x RTU. For information about installing the A730SD or A730MD, refer to the addVANTAGE A730 User Guide Version 3.4x. For information about installing the A840, refer to the Base Station, A840 Telemetry Gateway and Wireless Modem A440 User Guide.
Installing the RTU Fig. 1: Fig. 2: 2.2 addWAVE RTU (top) addWAVE RTU (bottom) Installing the RTU The following restrictions apply: • Note: Note: 10 In general, the typical “line-of sight” distance the RTU can communicate is 10 km (6 miles). This is valid if both the RTU and its partner device are mounted on a 3 m mast (9 ft.); the results may vary under different conditions, and you can sometimes achieve greater distances. The above does not apply for the A733GSM RTU.
Using the A73x RTU 2.3 Special notes for the A733GSM RTU The A733GSM RTU is based on a GSM module which employs a GSM cellular network to transmit the telemetry data. Before you install such a device you must make sure that there is sufficient signal for proper operation of the RTU on the site you plan to use it; this is done best by using a standard cellular phone operated by the same cellular provider.
Special notes for the A733GSM RTU 3. Raise the holder top and slide the SIM card into it (Fig. 4, center). 4. Snap the holder top back on and slide it back as shown again by the red arrow depicted in Fig. 4, right. 5. Mount the lid back, taking care that the rubber gasket sealing the box is not out of place and free of dust or dirt. WARNING: Be sure to mount the rubber gasket properly, so that the unit’s IP65 environmental protection is not affected. 6.
Using the A73x RTU • the GSM modem is on • there is a valid SIM card inserted • the SIM card was activated with a valid PIN code. Additional information is also listed but this should be of no concern for the user, except the PUK required entry. If this parameter is Yes, it can be the result of entering a wrong PIN code three times in a row. You can see this also in the last string displayed by the GSMSTAT command (number of retries left).
More about the LED tool 4. Using a hammer, drive the 80cm aluminum rod into the ground. Prior to that put an Adcon plastic cap into the top of the pole and secure it with a pie clamp in order to protect the top of the pole from damage. 5. Using the pipe clamp supplied fasten the solar panel onto the pole. Make sure that the panel is facing south (north if you are located in the southern hemisphere) and out of the way of the A73x RTU.
Using the A73x RTU Note: 2.6 New A73x RTUs are delivered with their internal batteries unformatted, meaning they are completely discharged, and you should install them only on sunny days. The battery will be fully charged after two consecutive sunny days, but you should get an LED light-up after several minutes of charging in the sunlight.
Maintaining and servicing the RTU Radio Activity No Low Heavy Low Low Heavy Sensor Sampling (samples/15 min) No sensors No sensors No sensors 3 15 15 Table 1: Note: Average Consumption (mA) Estimated Operation (days) 0.85 2.8 5 4.2 6.3 9 132 40 22 26 17 12 A73x Device Operation Time Low radio activity means that one base station and between one and three A730MDs/A73xs or A730SDs are active on the same operating frequency as the A73x remote station under test.
Using the A73x RTU Fig. 7: Unplugging the PCB Connector 3. Unscrew the four screws of the plastic cover that holds the battery pack in place, then remove the cover. Fig. 8 shows the A733 battery pack inside the RTU. Fig. 8: A733 Battery Pack 4. Remove the battery pack and replace it with a new one (obtainable from Adcon). 5. Replace the plastic cover and screw the four screws back in. 6. Carefully remove the rubber gasket in the lid and replace it with the one supplied with the battery. 7.
Maintaining and servicing the RTU 18
Performing Advanced Functions 3 Performing Advanced Functions With the appropriate knowledge, you can configure the A73x devices in the field by using a HyperTerminal window. To configure the RTU, you will need a special serial cable adapter (not supplied, available from Adcon). Do not try to configure your A73x devices if you are not sure what to do—the unit may not communicate with the remote measuring station or function with the addVANTAGE software.
Understanding connectors Switched Battery Cabling 1 Digital I/O Cabling 2 7 1 6 2 5 4 3 Pulse Counter Fig. 9: Cabling 3 Ground Pins on an I/O Connector (Top View) Using Adcon’s 7-pin Y-cable lets you attach more than one sensor to one connector. CAUTION: 3.1.2 To avoid cabling conflicts, first verify in the addVANTAGE software that the sensor combination in the configuration you want is allowed. If there are no conflicts, you can physically attach the sensors to the A73x RTU.
Performing Advanced Functions 5 + Battery (5,6 to 10V) - Fig. 11: 4 1 3 2 Short A73x Connection with External Battery If you want to use the internal battery with a different power supply (charger) than the provided solar panel, disconnect the solar panel and use the configuration shown in Fig. 12. + Charger (9 to 10V, 100 to 300mA) 5 4 1 3 2 Short - Fig.
Serial communication protocol 3.3 Serial communication protocol This protocol is based on a master sending commands and a node answering; the whole communication is conducted in plain ASCII, as strings. When exchanging numbers, they are represented in decimal format. All commands are terminated with a CR/LF combination. All responses (answers) are terminated with the # character. 3.3.1 General format of a command The commands have the following format: ID Command Param1 Param2 ... ParamN • Note: 3.3.
Performing Advanced Functions The answer string may contain any number of spaces or CR/LF characters between its components; however, after the terminator (#) no other characters are allowed. 3.4 Using terminal commands Following is a list of available commands and an explanation of their use. Note: You can type uppercase or lowercase characters because the commands are not case sensitive. CMDS AVAILABLE FOR A731 A732 A733 A733GSM DESCRIPTION Returns a list of supported commands.
Using terminal commands DESCRIPTION Sets/returns the operating frequency. PARAMETERS The operating frequency and step (Hz), or none in the GET version. RETURNS The actual frequency and step, in Hz. REMARKS GET/SET. Not applicable to the A733GSM. REMOTE Yes, SET only.
Performing Advanced Functions SLOT CAUTION AVAILABLE FOR Changing these parameters may adversely affect the ability of the device to operate for extended periods under low solar radiation conditions. A731 A732 A733 A733GSM DESCRIPTION Sets/returns the node’s sampling interval and rate. PARAMETERS The interval (60 - 65535) and rate (0 - 255).
Using terminal commands REMOTE Yes, SET only. EXAMPLE PMP 65 72 9193 PMP 0 # PMP 9193 PMP 65 72 0 # ANLG AVAILABLE FOR A731 A732 A733 A733GSM DESCRIPTION Sets/returns various parameters of the analog subsystem (for example, the sampling/averaging method used for individual data acquisition channels). PARAMETERS A control byte specifying the command and the analog input channel number the command is acting on: Channel Number Command Code Fig. 14: The ANLG Control Byte Layout.
Performing Advanced Functions Code Description 0100 SSMAA – Set Sampling Method to Arithmetic Average. The specified analog channel will be instructed to store the arithmetic average of all sampled values 0101 SSMCA – Set Sampling Method to Circular Average. The specified analog channel will be instructed to store the circular average of all sampled values. 0110 SSMF – Set Sampling Method to First. Only the first sampled value will be stored in each slot 0111 SSML – Set Sampling Method to Last.
Using terminal commands Code Description 1101 ENONTR – Enable Notify On Negative Threshold Reached Returns Result (OK or ERROR) 1110 Result (OK or ERROR) 1111 Parameters The channel number and the threshold (16 bit value) ENOL – Enable Notify if Out of The channel numLimits ber and the limit values (16 bit value), first the lower and then the higher limit. ENIL – Enable Notify if Inside the The channel numLimits.
Performing Advanced Functions REMARKS The general behavior is that an ANLG command issued on a certain input channel will override any previous ANLG commands affecting that channel. REMOTE The A733 cannot issue ANLG commands remotely, but can execute them.
Using terminal commands The data block returned will typically contain a number of data frames (telegrams). The structure of a block is as follows: dd mm yyyy hh mm ss si ft d1 d2 ... dn dd mm yyyy ... dn cs where: • dd mm yyyy is the date • hh mm ss is the time • si is the size of the frame (21 for frame type 37, 13 for frame type 38) • ft is the frame type (37 for the A733, 38 for A732 and A731) • d1 d2 ...
Performing Advanced Functions b7 SC b0 Dig6 Dig5 Dig4 Dig3 Dig2 Dig1 Dig0 SC-Battery Charge (0-off, 1-on) Fig. 16: Dig n – Digital I/O n The Digibyte The remote version is limited to a single frame. An example of such a command is given below: 9999 DATA 9999 30/9/1999 14:50:00 9999 DATA 30 9 1999 14 54 55 21 37 255 255 77 0 0 0 0 89 156 126 20 0 0 0 0 0 0 0 0 0 3197 0 # Notice that if you need to get data that is not the last (newest) slot remotely from a device, the ID must be supplied twice.
Using terminal commands PARAMETER If the parameters are missing, the command will destroy all the data in the EEPROM file. If a parameter is given, the EEPROM type is defined (data won’t be destroyed). Following EEPROM types are currently defined: • 0 – 16 Kbytes (e.g. model 25128) • 1 – 32 Kbytes (e.g. model 25256) RETURNS Nothing. REMARKS SET only. REMOTE Yes, SET only.
Performing Advanced Functions • pmp_low and pmp_high are the programmed values with the PMP command (irrelevant for the A733GSM) • type is used to represent the device type; following types are assigned currently: 0 for A730MD 1 for A720 2 for A730SD 3 for A720B 4 for A733 5 for A723 6 for A440 7 for A733 GSM 8 for A731 9 for A732 • slot and samples are the actual values programmed by means of the SLOT command • po is the power output of the device during the last frame sent; this value is relative
Using terminal commands • Code 0000 Description RDP – Read Data Port. This command reads the whole 16-bit port and returns its value; the Port Number has no significance for this command Parameters None Returns A 16-bit integer and the result (OK or ERROR). Only the lowest four significant bits reflect valid ports for the A733 0001 RDDR – Read Data Direction Register.
Performing Advanced Functions Code Description Enable Registers; the Port Number has no significance for this command. Parameters Returns 1001 CB – Clear the specified bit. The port number Result (OK or ERROR). 1010 SB – Set the specified bit. The port number Result (OK or ERROR). 1011 XB – Exclusive Or the specified bit. The port number Result (OK or ERROR). 1100 MFR – Monostable function, start with the specified bit in OFF state (reset). The port Result (OK or number, the ERROR).
Using terminal commands input and then an MFR (monostable function) was issued, the port automatically switches to output. A new MFR or similar function clears the status of the port and starts from scratch, even if the previous command was not finished. The A733 cannot issue the PORT command remotely, but can execute it.
Performing Advanced Functions REMARKS The system stops, and exits the command only when a key is pressed. This command returns no message. Not applicable to the A733GSM. REMOTE No. EXAMPLE TX 9193 TX 0 # TX 1 9193 TX 0 # TX 5 9193 TX 0 # B AVAILABLE FOR A731 A732 A733 A733GSM DESCRIPTION Sends a broadcast frame. PARAMETERS None. RETURNS A data block. REMARKS After the device sends the broadcast frame, it will listen for answers. All valid answers will be listed with their IDs.
Using terminal commands VER AVAILABLE FOR A731 A732 A733 A733GSM DESCRIPTION Requests the firmware version of the device. PARAMETERS None. RETURNS The current version. REMARKS GET only. REMOTE No. EXAMPLE VER 9193 VER 1.0.17 0 # Note: This command is provided only for compatibility with older units. The host software may use this command to identify the unit it is communicating with.
Performing Advanced Functions Note: For further information about the significance of the above terms please consult also the SDI-12 standard specification, version 1.3 (http://www.sdi-12.org). REMARKS SET/GET. REMOTE Yes. EXAMPLE 12225 sdi 12225 sdi AWmVd 3 0 M0 OK # 0x9 0 M2 0x20 7 M5 0x1 0 DATASDI AVAILABLE FOR A731 A732 A733 A733GSM DESCRIPTION Returns a slot of SDSI-12 sensor data, if any. PARAMETERS Offset and date/time, both optional.
Using terminal commands A733 RF incoming RF outgoing Digibyte I/O A Pulse Counter I/O B Pulse Counter I/O C Pulse Counter I/O D Pulse Counter Battery I/O A Cabling 1 I/O A Cabling 2 I/O A Cabling 3 I/O B Cabling 1 I/O B Cabling 2 I/O B Cabling 3 I/O C Cabling 1 I/O C Cabling 2 I/O C Cabling 3 I/O D Cabling 1 I/O D Cabling 2 I/O D Cabling 3 SDI count SDI offset SDI available SDI data block Fig.
Performing Advanced Functions • SDI value (floating point). (see also the example below) For additional information on the significance of the SDI address, method and index, please see also the SDI-12 standard specification (http:// www.sdi-12.org). The digibyte is similar to the DATA command: b7 SC b0 Dig6 Dig5 Dig4 Dig3 Dig2 Dig1 Dig0 SC-Battery Charge (0-off, 1-on) Fig. 19: Dig n – Digital I/O n The Digibyte The remote version is limited to a single frame. REMARKS GET only. REMOTE Yes.
Using terminal commands PARAMETERS: 0: let processor enter power save mode and thus not catch "fast" pulses. 1: enable RTU to count "fast" pulses. NONE: display current setting. RETURNS: The current setting, or the commands success or error code. REMARKS: GET/SET, starting from RTU firmware version 2.2.0. REMOTE: No. EXAMPLE: FPC 193 FPC 0 0 # FPC 1 193 FPC 0 # FPC 193 FPC 1 0 # GSMPIN A731 AVAILABLE FOR A732 A733 A733GSM DESCRIPTION Allows entering the PIN code for activating the SIM card.
Performing Advanced Functions RETURNS Result: a list of current status parameters. The list is self-explanatory. REMARKS GET only. Valid for the A733GSM RTU only. REMOTE No. EXAMPLE GSMSTAT GSM modem on: SIM card found: PIN set: PIN accepted: Sleepmode OK: PUK required: Default IMEI nr: Attempts left to 0 # Note: 3.5 Yes Yes Yes Yes Yes No No enter PIN: 3, PUK: 10 The A733GSM RTU can be called via the GSM interface from a standard modem.
Returned errors list 3.6.1 Command line interpreter 1 — nonexistent command 2 — command line buffer overflow (input line too long) 3 — internal error 4 — reserved 5 — missing or false parameters in command 6 — operation not implemented 7 — remote operation not allowed 8 — Invalid IMEI checksum number 3.6.
Performing Advanced Functions 3.6.
Specifications 4 Specifications The A733 was intended to fulfill the specification of the EN 300 220-1, and ETSI 300 113, as well as the FCC Part 90, Subpart J of the CFR 47. Table. 2 shows the main operational parameters of the A733. Note: The parameters below are measured with an A733 + A431 combination.
Returned errors list Parameter Digital I/O One Level Pulse Counters Pulse Counter Speed Pulse Counter Input Levels (Counting on Leading Edge) Sensor Supply Current (Switched Output) Sensor Settling Time Data Memory Size Sampling Rate Storage Interval Min 4 2 0 0 Receiver (Not Valid for A733GSM) Sensitivity (12 dB S/S+N) Image Frequency Attenuation (1st IF=45MHz) Local Oscillator Leakage Adjacent Channel Attenuation RSSI dynamic Operating current (incl.
Specifications Parameter Min Typ Spurious Radiation Adjacent Channel Power (12,5kHz mode) Adjacent Channel Power (25kHz mode) Operating current(incl. On-board microcontroller) Table.
Index 5 Index A A440 ....................................................15 A730MD ..............................................10 A733GSM Communication distance................10 PIN code ........................................12 PUK ................................................13 SIM Card ........................................11 Special Notes .................................11 A840 Telemetry Gateway....................15 addVANTAGE Software......................15 Advanced Functions............
Index D R DATA...................................................29 Returned error .................................... 44 DATASDI.............................................39 RSSI ................................................... 24 Distance ..............................................10 FREQ ..................................................23 RTU Battery ........................................... 15 Changing the battery ..................... 16 configuration ..............................