ADX DAS HPR User Manual Version 0.1 3116 West Vanowen St. Burbank, CA 91505 Tel: 818‐840‐8131 Fax: 818‐840‐8138 www.adrftech.com Advanced RF Technologies, Inc.
Information in this document is subject to change without notice. Advanced RF Technologies, Inc. 1996‐2015. All rights reserved. Please send comments to: E‐Mail: Phone: Fax: info@adrftech.com (818) 840‐8131 (800) 313‐9345 (818) 840‐8138 Address: Advanced RF Technologies, Inc. Attention: Technical Publications Department 3116 Vanowen St. Burbank, CA 91505 USA www.adrftech.com Advanced RF Technologies, Inc.
Revision History Version 0.1 Author CCK Descriptions Date Initial Release 05/13/15 Change List Version Change list Advanced RF Technologies, Inc.
Table of Contents 1. Introduction ......................................................................................................................................................14 1.1 1.2 Highlights ...................................................................................................................................................14 Head End Parts List ....................................................................................................................................
3.1.4.4 Communication Port................................................................................................................. 33 3.1.5 Power Supply Unit (ADX‐H‐PSU)......................................................................................................... 33 3.1.5.1 LEDs ..........................................................................................................................................33 3.1.5.
7. Commissioning ..................................................................................................................................................55 7.1 Pre‐Commissioning Check ......................................................................................................................... 55 7.1.1 Verify cable connections .................................................................................................................... 55 7.1.2 Connect to the Web‐GUI ...........
8.2.3.2 Control – BCU ........................................................................................................................... 86 8.2.3.3 Control – RFU ............................................................................................................................ 87 8.2.3.4 Control – ODU........................................................................................................................... 91 8.2.3.5 Control – RH Hub .................................
Figures Figure 1‐1 Figure 1‐2 ADX DAS HE Quick View ..................................................................................................................... 19 ADX DAS HPR Quick View ................................................................................................................... 20 Figure 2‐1 Figure 2‐2 Figure 2‐3 ADX DAS Block Diagram (4BANDS) ................................... 오류! 책갈피가 정의되어 있지 않습니다. ADX DAS Topology ......................................................
Figure 6‐5 Figure 6‐6 Figure 6‐7 Figure 6‐8 Figure 7‐1 Figure 7‐2 Figure 7‐3 Figure 7‐4 Figure 7‐5 Figure 7‐6 Figure 7‐7 Figure 7‐8 Figure 8‐1 Figure 8‐2 Figure 8‐3 Figure 8‐4 Figure 8‐5 Figure 8‐6 Figure 8‐7 Figure 8‐8 Figure 8‐9 Figure 8‐10 Figure 8‐11 Figure 8‐12 Figure 8‐13 Figure 8‐14 Figure 8‐15 Figure 8‐16 Figure 8‐17 Figure 8‐18 Figure 8‐19 Figure 8‐20 Figure 8‐21 Figure 8‐22 Figure 8‐23 Figure 8‐24 Figure 8‐25 Figure 8‐26 Figure 8‐27 Figure 8‐28 Figure 8‐29 Figure 8‐30 Figure 8‐31 Figure 8‐32 Figur
Figure 8‐42 Figure 8‐43 Figure 8‐44 Figure 8‐45 Figure 8‐46 Figure 8‐47 Figure 8‐48 Figure 8‐49 Figure 8‐50 Figure 8‐51 Figure 8‐52 Figure 8‐53 Figure 8‐54 Figure 8‐55 Figure 8‐56 Figure 8‐57 Figure 8‐58 Figure 8‐59 Figure 8‐60 Figure 8‐61 Figure 8‐62 Figure 8‐63 Figure 8‐64 Figure 8‐65 Figure 8‐66 Figure 8‐67 Figure 8‐68 Figure 8‐69 Figure 8‐70 Figure 8‐71 Figure 8‐72 Figure 8‐73 Figure 8‐74 Figure 8‐75 Figure 8‐76 Figure 8‐77 Figure 8‐78 Figure 8‐79 Figure 8‐80 Figure 8‐81 Figure 8‐82 Figure 8‐83 Figure 8
Figure 8‐95 Figure 8‐96 Figure 8‐97 Figure 8‐98 Figure 8‐99 Figure 8‐100 Figure 8‐101 Figure 10‐1 Figure 10‐2 Setting Backup (After)....................................................................................................................... 111 Setting Restore .................................................................................................................................112 SNMP V1/V2 ...............................................................................................
Tables Table 1‐1 Table 1‐2 Table 1‐3 Table 1‐4 Table 1‐5 Table 1‐6 Table 1‐7 ADX‐H‐NMS Parts List ......................................................................................................................... 15 ADX‐H‐BCU Parts List .......................................................................................................................... 16 ADX‐H‐RFU Parts List ........................................................................................................................
Terms and Abbreviations The following is a list of abbreviations and terms used throughout this document.
1. INTRODUCTION Up to (8) frequency bands in one body: Currently the ADX supports 700 MHz (Lower A, Lower B, Lower C, and Upper C), 700MHz Public Safety & Upper D support, Cellular, PCS, SMR800/SMR900, AWS, WCS and BRS‐TD LTE bands. ADX‐HPR‐7F43, ADX‐HPR‐C43, ADX‐HPR‐W, ADX‐HPR‐P46, ADX‐HPR‐A46, ADX‐HPR‐BT46 메모 [C1]: 표기 방법 검토 W43‐>W44.8‐>W 로 수정 1.1 Highlights Modular Structure (HE) ‐ ‐ Supports multi bands service (700MHz, 700MHz PS, Cell, PCS, AWS, SMR800/SMR900, WCS, BRS‐ TD LTE, etc.
1.2 Head End Parts List 1.2.1 ADX‐H‐NMS‐PKG Parts List Table 1‐1 Label A B C D E F G H ADX‐H‐NMS Parts List Quantity Description 1 1 1 1 1 1 1 1 28 1 ADX‐H‐NMS‐PKG (Network Management System Package) ADX‐H‐NMS ADX‐H‐PSU (AC to DC Supply) ADX‐H‐CHC (Head End Channel Combiner) AC Power Cord RJ‐45 Crossover Cable Ground Cable Documentation CD (User Manual, Quick Start Guide and Troubleshooting Guide) Wall Anchor Bolt Set SMA terminators L‐mounting Brace A. B. C. D. G.
1.2.2 ADX‐H‐BCU Parts List Table 1‐2 ADX‐H‐BCU Parts List Label Quantity Description A B C D E 1 6 2 1 2 ADX‐H‐BCU (Band Combiner Unit) N‐Type terminators NM to NM RF Jumper Cables (3ft) Data/Power Cable Chassis mounting brace A. B. 1.2.3 C. D. ADX‐H‐RFU Parts List Table 1‐3 ADX‐H‐RFU Parts List Label Quantity Description A B C 1 2 2 ADX‐H‐RFU (RF Unit) N‐Type Terminators SMA Male RF Jumper Cables A. Advanced RF Technologies, Inc. B. C. 16 E.
1.2.4 ADX‐RACK‐ODU Parts List Table 1‐4 ADX‐RACK‐ODU Parts List Label Quantity Description A B C 1 1 1 ADX‐RACK‐ODU Data/Power Cable Chassis Mounting Brace A. B. 1.2.5 C. 메모 [H4]: ‐X 추가 ADX‐H‐ODU4‐X Parts List Table 1‐5 ADX‐H‐ODU4 Parts List Label Quantity Description A B C 1 2 2 ADX‐H‐ODU4 (4‐port Optical Unit) SMA‐M Terminators SMA‐M to SMA‐M RF Jumper Cable (3ft) A. B. 1.2.6 C.
B. C. 1.3 High Power Remote Unit Parts List 1.3.1 ADX‐R‐xxx46/44.8/43M (HPR) Parts List Table 1‐7 HPR Parts List Label Quantity Description A B C D E F G H I 1 4 1 1 1 4 1 1 1 ADX‐R‐xxx46/44.8/43M (Main HPR) N type‐M terminators USB Cable AC cable Ground cable Anchor Bolt Manual CD Install guide Wall mount template Advanced RF Technologies, Inc.
1.4 ADX DAS Quick View 1.4.1 HE Quick View 1.4.
1.4.3 RU Quick View 메모 [C6]: 사진 수정 필요 Controller per band RAU Duplexer HPA ORU RCU Optic port PSU Splitter Unit Filter extension port_1 BAN D 1 SER VER BAN D2 SER VER EX_ F1 _ IN BAN D 3 SER VER EX_ F1 _ O U T BAN D4 SER VER Filter extension port_2 C PL (-3 0 d B) Server antenna port C PL (- 3 0d B ) C PL (-3 0 d B ) EX _F 2 _IN C PL ( -3 0 d B) EX _ F2 _ O U T Local GUI port AC IN 1 1 0 V Optic port BAN D5 SER VER BAN D6 SER VER PO WER O PTIC A= AC_L B= AC_N C= F.
1.5 Warnings and Hazards WARNING! ELECTRIC SHOCK Opening the ADX DAS could result in electric shock and may cause severe injury. WARNING! EXPOSURE TO RF Working with the ADX DAS while in operation, may expose the technician to RF electromagnetic fields that exceed FCC rules for human exposure. Visit the FCC website at www.fcc.gov/oet/rfsafety to learn more about the effects of exposure to RF electromagnetic fields.
Ethernet Instructions: This equipment is for indoor use only. All cabling should be limited to inside the building. FCC Part 15 Class A NOTE: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment.
Laser Safety Fiber optic ports of the ADX DAS emit invisible laser radiation at the 1310, 1550nm wavelength window. To avoid eye injury never look directly into the optical ports, patch cords or optical cables. Do not stare into beam or view directly with optical instruments. Always assume optical output is on. Only technicians familiar with fiber optic safety practices and procedures should perform optical fiber connections and disconnections of the ADX DAS and the associated cables.
2. 메모 [C10]: Block Diagram 삭제(15.07.28) ADX‐DAS CONFIGURATION _조찬기 2.
2.2 Configuration 2.2.
2.3 ADX‐DAS Scalability Table 2‐1 HE ADX‐DAS Scalability Unit Scalability Supported band 700M, Cellular, AWS, PCS, SMR800/900, PS700, WCS, BRS TD‐LTE RFU Up to 8 NMS 1 Channel Combiner 1 Remarks up to 6: card type 7th & 8th RFU: 19” rack type Optic Unit Up to 4 Band Combiner Unit Up to 4 To support multiple carriers 1 Capable of supplying power to 8 RFUs, 4 BCUs, 4 ODU racks and NMS.
3. ADX OVERVIEW 3.1 Head End The head end unit must always be connected to the Base Station using a direct cabled connection. This system has not been approved for use with a wireless connection via server antenna to the base station.
3.1.1 ‐ ‐ ‐ ‐ Supports SNMP v1, v2, and v3 (get, set & trap) and web‐based GUI Interface. Monitors alarms and status Provides control interfaces with all subordinate modules Provides overall DAS structure via the auto tree update function ‐ ‐ Size: 19.0 x 12.1 x 1.7 inches Weight: 5.
3.1.1.2 Ethernet Port The Ethernet port can be used to communicate directly with the ADX DAS using a RJ‐45 crossover cable or can also be used to connect the ADX DAS to an external modem box. HOST HE VIEW Figure 3‐4 REMOTE RU VIEW Ethernet Port 3.1.1.3 Host/Remote Switch The Host/Remote Switch allows the user to switch the default Repeater IP, Subnet Mask, and Gateway of the repeater to an alternative setup.
3.1.
3.1.2.2 RF Ports 3.1.2.2.1 DL IN/UL OUT & DPX ports DL IN/UL OUT & DPX Ports (refer to Figure 3‐7) are located at the back of RFU and can be connected directly to the BTS. The RFU can support incoming signal strength from 0 to 25dBm. DL OUT/UL IN 3.1.2.2.2 DL OUT/UL IN Ports (refer to Figure 3‐7) are located at the front of the RFU and connect directly to the HE Channel Combiner (ADX‐H‐CHC). 3.1.2.3 Communication Port The ADX‐H‐NMS monitors and controls the RFU via this port.
3.1.4 Optic Unit (ADX‐RACK‐ODU, ADX‐H‐ODU4/ADX‐H‐ODU1) Figure 3‐11 VHF UL UL OUT VHF DL ADX‐RACK‐ODU Front & Rear view DL IN VHF UL UL OUT VHF DL DL IN OPT LINK 4 LINK 3 Figure 3‐12 LINK 1 LINK 4 LINK 3 LINK 2 LINK 1 ADX‐H‐ODU4 and ADX‐H‐ODU1 Installed in ADX‐RACK‐ODU Functions & Features Converts signal from RF to optic and transports signals up to a maximum of 10Km (optical 5dBo loss including optical connection loss).
3.1.4.2.1 DL IN/UL OUT The combined downlink signal received from ADX‐H‐CHC is transferred to the DL IN 1(or 2) at the back of ODU. The UL OUT port connects any of the ports on back of the ADX‐H‐CHC labeled UL 1 ~8. 3.1.4.2.2 VHF DL/VHF UL VHF DL/UHF UL ports are used to support Public Safety in the VHF & UHF frequency bands. VHF/UHF signals for Public Safety bypass the ADX‐H‐CHC and connect directly to the VHF DL/UHF UL ports of the ADX‐H‐ODU. 3.1.4.
PO WE R C HG S LO TS W BA A C TT FA I DC L FA IL ADX‐H‐PSU has the following LEDs on the front panel as shown in Figure 3‐18.
(WARNING: The circuit switch on the ADRF‐BBU must be set to the OFF position before connecting the ADRF‐ BBU to the ADX‐H‐PSU to prevent damage to the ADX‐H‐PSU or the ADRF‐BBU and personal injury.) Note: Please contact ADRF Technical Support for assistance if you are unfamiliar with the installation procedure of our battery box. The Battery Install port is used to let ADX‐H‐NMS know if an ADRF‐BBU is connected to the ADX‐H‐PSU or not.
Soft Fail Solid Yellow Solid Green Soft Fail alarm exist in the RFU No Soft Fail alarms are present in the RFU 3.1.6.2 RF Ports 3.1.6.2.1 DL IN/UL OUT & DPX ports DL IN/UL OUT & DPX Ports are located at the back of BCU and connect directly to a BTS. 3.1.6.2.2 DL OUT/UL IN DL OUT/UL IN Ports are located on the back of ADX‐H‐BCU and connect directly to the ADX‐H‐RFU. 3.1.6.3 Communication Port ADX‐H‐NMS monitors and controls the ADX‐H‐BCU via this port.
BAN D 1 SER VER BAN D2 SER VER C PL (-3 0 d B) EX _ F1 _ IN C PL ( -3 0 d B) C PL (- 3 0d B ) EX_ F2 _ IN AC IN 1 1 0V BAN D 3 SER VER EX_ F1 _ O U T C PL (-3 0 d B) EX _ F2 _ O U T BAN D5 SER VER BAN D 6 SER VER O PTIC A B A =AC _L B= AC N _ C =F. G C A C PL ( -3 0 d B) B PO WER GUI C PL (-3 0 d B) RUN 3.2.1.1.2 Extension Filter port (N type) ‐ ‐ BAN D 4 SER VER EX_F1_IN, EX_F1_OUT: extension of additional Filter Port EX_F2_IN, EX_F2_OUT: extension of additional Filter Port 3.2.1.
OPTIC Figure 3‐26 Optic connection 3.2.1.
Figure 3‐28 HPR LED Table 3‐6 Master HPR LED Specifications ADX DAS‐Module Power 3.2.3 Solid Green OFF Specifications Module power is ON Module power is OFF AC On/Off Switch, AC Port Figure 3‐29 HPR AC Port Figure 3‐29 HPR AC Switch The AC Power on/off switch is located on PSU in the enclosure of each ADX‐HPR. Advanced RF Technologies, Inc.
The ADX‐HPR is operated at the only 110V AC. The socket‐outlet shall be installed near the equipment and shall be easily accessible (WARNING: The AC switch must be set to OFF before cable connection to avoid equipment damage and personal injury.) (WARNING: To avoid damage, be sure 110V AC for operation of ADX‐HPR.) (CAUTION: DOUBLE POLE/NEUTRAL FUSING.) The procedure for connecting HPR AC S/W OFF AC cable connection Optic connection RF cable connection RS 485 connection AC S/W ON 3.2.
(WARNING: The DC switch must be set to OFF before cable connection to avoid equipment damage and personal injury.) (WARNING: To avoid damage, be sure ‐48V(‐36~‐76V) DC for operation of ADX‐HPR. (CAUTION: DOUBLE POLE/NEUTRAL FUSING.) The procedure for connecting HPR DC S/W OFF DC cable connection Optic connection RF cable connection RS 485 connection DC S/W ON 4. CABLE CONNECTION 4.1 Head End Connection Diagrams 4.1.
Figure 4‐1 4.1.2 HE Cable connection (1 ADX‐RACK‐ODU +1 BCU) Rear Head End Connection View with (4) ADX‐RACK‐ODU units Advanced RF Technologies, Inc.
Figure 4‐2 HE Cable connection (4 ADX‐RACK‐ODUs) 4.2 High Power Remote Unit Connection Diagrams ‐ Ethernet cable for RS 485 is crossover type 메모 [C21]: 수정(CK) BAN D1 SER VER OPTIC LINE BAN D 2 SER VER C PL (- 3 0d B ) BAN D3 SER VER EX _ F_ O U T EX _ F_ IN C PL (-3 0 d B) C PL (-3 0 d B) BAN D 4 SER VER C PL (-3 0 d B) O PTIC BAN D 5 SER VER AC IN 1 1 0 V BAN D 6 SER VER A B PO WER A = AC_L B = AC_N C = F.
5. MOUNTING METHOD 5.1 Head End BA TT STS FA IL FA IL LO W DC AC CH G FA IL -H O W ER FA IL HA -R RD FA IL HA -H RD FA IL LI -R NK FA IL -H LI NK FA IL -R P SO FT P OW ER Rack Mount SO FT 5.1.1 Figure 5‐1 HE Rack Mount (Front & Rear view) Expandable up to 4 ADX‐RACK‐ODUs, 4 BCUs and 2 AUX CHs Advanced RF Technologies, Inc.
FA IL -H FA IL -R LIN K LIN K FA IL -R D IL -H HA R D AT T B ST S FA IL C C A FA FA IL -R AR D H E R HG LO W PO W C FA IL -H ER W FT FT S O PO Figure 5‐2 FA IL Wall Mount SO 5.1.2 HE Wall Mount (Top View) Expandable up to 3 units (ODU, BCU) or max 3U (132mm) ‐ ODU or BCU will be stacked up above basic 19” HE chassis which includes NMS, RFU, PSU and CHC Advanced RF Technologies, Inc.
5.2 HPR 5.2.1 Wall Mount ADX‐HPR is support only wall mount. Figure 5‐3 6. HPR Wall Mount INSTALLATION 6.1 Pre‐Installation Inspection Please follow these procedures before installing ADX HPR equipment: o Verify the number of packages received against the packing list. o Check all packages for external damage; report any external damage to the shipping carrier.
6.2 ADX DAS Installation Procedure 6.2.1 HE Installation Procedure CAUTION: ADX DAS HE should be installed inside building only. 6.2.1.1 Installing a ADX DAS HE in a rack The ADX HE chassis mounts in a standard 19” (483mm) equipment rack. Allow clearance of 3” (76mm) at the front and rear, and 2” (51mm) on both sides for air circulation. No top or bottom clearance is required. Consideration: ‐ Eight mounting holes are located on 4 corners of ADX HE to attach it to the 19” rack.
Figure 6‐1 Advanced RF Technologies, Inc.
6.2.1.2 Wall mounting the ADX DAS HE If the ADX HE chassis is being mounted to a wall, then allow clearance of at least 17” (430mm) on the top (front side of HE) and 2” (51mm) on the bottom (rear side of HE) and 2” (51mm) on both sides and front for air circulation.
6.2.1.2.1 Installing added rack type modules into basic HE chassis Additional modules such as the ADX‐RACK‐ODU and ADX‐H‐BCU can be mounted to the Chassis (ADX‐H‐CHA) using the included mounting brackets that come with the add‐on modules. A maximum of up to 3 addon modules (ODU, BCU) can be mounted to the chassis ‐ ODU or BCU will be stacked up above basic 19” HE chassis which includes NMS, RFU, PSU and CHC Figure 6‐3 Advanced RF Technologies, Inc.
6.2.
Figure 6‐4 Advanced RF Technologies, Inc.
6.3 Grounding A ground cable is included in the box. The grounding terminals are located at the rear of the ADX HE and RU. The grounding cable should be properly connected before powering on the equipment. Figure 6‐5 Figure 6‐6 Ground Cable Connection (HE rear side) Ground Cable Connection (HPR dual side) Round terminals located on the side of a 1.25mm²(16AWG)or more wires Using permanently connected to earth. Advanced RF Technologies, Inc.
6.4 Optic Port Cleaning We recommend cleaning optic connector using a dry optical cleaning swab or tissue in a dry environment as needed. We recommend cleaning the optic connectors only if the expected optic loss is higher than the loss reported in the Web‐GUI by 1.5dBo. (Figure 6‐7) When optic connector are not in use, the port should be covered with a protective dust cap.
7. COMMISSIONING The commissioning process is composed of the following: ‐ Pre‐Commissioning Check (refer to section 7.1) ‐ Optic Commissioning (Optic loss compensation) (refer to section 7.2.1) ‐ HE commissioning (refer to section 7.2.2) ‐ RU commissioning (refer to section 0) ‐ Commissioning verification (refer to section 0) 7.1 Pre‐Commissioning Check 7.1.1 Verify cable connections Before powering up units, check all RF cables, fiber cables, and power cables connections.
7.1.3 Check Navigation Tree Status Check whether the status of navigation tree is Lock or Unlock. The navigation tree should be in the “Unlock” state in when adding or removing active ADX components.
7.1.6 BOM Comparison & Check Band Configuration BOM comparison ‐ Check Band Configuration ‐ ‐ 7.1.7 On the System information page in the System menu, the list of all components connected to the ADX‐H‐NMS should match the ADX Navigation tree. This list can be used to verify BOM generated by designer or installer for all active components. Please note that passive components such as the ADX‐H‐CHC, ADX‐R‐CHC, ADX‐H‐PSU, and the ADX‐R‐4WS will not show up on this report.
7.2 Commissioning 7.2.1 Optic Commissioning Figure 7‐4 ODU Install page Navigate to the Install page of ADX‐H‐ODU (Figure 7‐4) Compare the values of measured optic loss (LD power – PD power) in the Web‐GUI with the actual optic loss which is typically measured at the time of installation of the fiber.
Optic loss compensation should be performed when the color of “Commissioning” button is orange. The “Commissioning” button will turn orange when the difference between the compensated attenuation and the actual compensated attenuation level is greater than 1.5 dB. Optic compensation can be performed by clicking the orange “Commissioning” button. The optic loss compensation for uplink and downlink are performed separately.
7.2.2 HE Commissioning HE commissioning is composed of HE BCU and HE RFU commissioning. The HE BCU is an optional component and should be used when WPSs’ signals are being used in the same frequency band. 7.2.2.1 Composite power To perform HE commissioning, the user should calculate downlink composite input level and add the proper amount of breath room required for rise in traffic. Information that is needed to calculate commissioning levels are: ‐ ‐ ‐ ‐ ‐ 7.2.2.1.1 7.2.2.1.1.
‐ If calculated composite HE DL input power exceeds the permitted maximum input range, then additional attenuation will need to be added to the BCU input port so that the calculated HE DL input power does not exceed 25dBm. The RFU DL input commission level is the combined DL Output ALC Level of the ADX‐H‐BCU which can be obtained from the Control page of the ADX‐H‐BCU. ‐ 7.2.2.1.2 7.2.2.1.2.
Total input per band 10.0dBm 10.0dBm HE Total Input 13.0dBm The RFU can now be commissioned with the 10dB of attenuation by using a DL input commission level of 18dBm. Table 7‐6 HE maximum downlink input level after adding 10dB attenuator to HE downlink input port WSP AT&T Total input per band 10.0dBm Back off per band for breathing 5.0dB 10.0dBm 5.0dB Estimated Total Max Input per band 15.0dBm 15.0dBm Estimated Total Max Input 18.0dBm Available Max Input 25.0dBm 7.2.2.1.2.
‐ The attenuation and DL output ALC level for the other ports are set based on the formula below to keep the power ratio between BCU ports.
7.2.2.1.3 HE BCU Commissioning When performing BCU commissioning, the user will need to enter the DL input commissioning level and Targeted DL Output Power Ratio for each RF path. Refer to section 7.2.2.1 to calculate DL input commissioning level. If a port is not being used, the DL Input Commissioning Level should be set to “disabled”. 7.2.2.1.3.
7.2.2.1.4 HE RFU commissioning If a BCU is being used in the system, the BCU should be commissioned before commissioning the HE RFU. For RFU commissioning, the user will need to calculate the DL input commissioning level. Refer to section 7.2.2.1 to for information to determine the DL input commissioning level. 7.2.2.1.4.
7.2.3 HPR Commissioning HPR composite downlink output level can be determined using simulation tools like iBwave. User should simulate this output level in order to ensure that all service areas have sufficient coverage. The simulated composite DL output power value should not exceed the maximum output level of the HPR, which is 46/44.8/43dBm. The simulated composite DL output power value would be used as HPR DL commissioning output level.
7.3 DAS Install Verification 7.3.1 Setting SNMP & Remote IP Go to Install page of NMS (refer to section 8.2.4.1.4) When external modem box is connected, user should set SNMP & Remote IP information. 7.3.2 Verification through Web based GUI Go to System information page of System (refer to section 8.2.5.4.1) ‐ ‐ ‐ 7.3.3 Check if Remote Module with same frequency band exist more than one within one HPR. Check if there are any noncommissioned modules in HE or RU.
8. WEB‐GUI 8.1 Web‐GUI Setup The Web‐GUI allows the user to communicate with the DAS system either locally or remotely. To connect to the DAS system locally, you will need a laptop with an Ethernet port and a RJ‐45 crossover cable. To connect to the DAS system remotely, you will need to have an active internet connection and the ADX system must have and external modem box connected to the ADX. 8.1.
8.2 Administrator/User Mode 8.2.1 Common 8.2.1.1 Navigation tree Lock/Unlock When the system is “Locked”, a green lock icon will appear above the navigation tree. When the system is locked, new devices cannot be added. Any devices added to the system when the system is “Locked” will not be detected by the NMS. After a system has been commissioned properly, the system should be left in the “Locked” position. To unlock the system, click on the “Unlock System” button to the right of the icon.
8.2.1.3 Power Status Display the power source that is currently being used. Table 8‐3 Input Power Status Power Supply Status Display Image AC Battery 8.2.1.4 Commissioning Status Display whether or not the module has successfully been commissioned. Table 8‐4 Status Commissioning ICON Display Image Commissioned Not‐Commissioned 8.2.1.
8.2.2 Status Tab 8.2.2.1 Status – NMS Figure 8‐5 Status ‐ NMS The NMS Status page provides an overall view of how the system is performing. From the NMS Status page, the user can see what modules are connected to ADX DAS. In addition, the user can see if any alarms are present in the system and also the commissioning status of each module. 8.2.2.1.
Table 8‐5 Description Connected Display the number of modules physically connected to ADX DAS Soft Fail Display the number of soft fail present on each module Display the number of hard fail present on each module Link Fail Display the number of link fail present on each module Not Commissioned Display the number of non‐commissioned or commission failed module Commissioned Display the number of successfully commissioned module HE View / HPR View, System Scan Time HE View/RU View ‐ ‐ Paramet
8.2.2.1.4 HE Commissioning Status Display commissioning status of each HE component. Figure 8‐9 Table 8‐6 HE Commissioning status Description for HE Commissioning status Status Installed Status Commissioning Status 8.2.2.1.5 Display Description Physically Installed Physically Not‐Installed Success Failed or not commissioned Text is black Text is gray Green Gray Alarm Displays alarm status of the NMS.
8.2.2.2 Status – BCU Figure 8‐10 Status – BCU 8.2.2.2.1 Band Displays the bandwidth and the frequency ranges for DL and UL of the BCU module. Figure 8‐11 Status – BCU Band 8.2.2.2.2 Power & Atten Figure 8‐12 Status – BCU Power & Atten DL Commissioning Level: Displays the commissioning level for each individual RF path. If unit has not been commissioned, “Not Commissioned” will be displayed. Advanced RF Technologies, Inc.
8.2.2.2.3 DL Input: Displays the currently incoming signal strength of each RF path along with the composite DL input power of all 3 RF paths. Atten: Displays the attenuation values that the system is currently using which is defined by the power ratios specified by the user. DL Output: Displays the output value for each RF path along with the composite DL output power of all 3 RF paths. The DL Output level for each RF path will not exceed 5dBm and the composite output power will not exceed 10 dBm.
8.2.2.3 Status – RFU Figure 8‐15 Status – RFU 8.2.2.3.1 Band Displays the bandwidth and the frequency ranges for DL and UL of the RFU module. Figure 8‐16 Status – RFU Band 8.2.2.3.2 Power & Gain (Admin/User) Admin Mode‐ Displays the Downlink Input/output, Downlink/Uplink Attenuation, and Uplink Output. User Mode‐ Displays the Downlink Input, Downlink/Uplink Attenuation, and Uplink Output. Figure 8‐17 Power & Gain Display (Admin) Advanced RF Technologies, Inc.
Figure 8‐18 Power & Gain Display (User) Input [dBm]: Displays the Downlink RF input level which comes from the ADX‐H‐BCU or BTS. This value should be between 0 to 25 dBm. ALC Atten [dB]: The amount of attenuation that is being used by the system when ALC is active. Atten [dB]: The amount of attenuation that has been set manually by the user. Output [dBm]: The downlink/uplink output power of the RFU and NOT the output power of the RU. 8.2.2.3.3 Alarm Displays System, RF, and Power Alarms.
8.2.2.4 Status – ODU Figure 8‐19 Status ‐ ODU 8.2.2.4.1 Summary The Summary section displays the number of remote modules that are physically connected, the number of soft/hard/link fail alarms, and the number of Remote Module that have been commissioned and the number of Remote Module that need to be commissioned. Figure 8‐20 Summary (Status – ODU) Advanced RF Technologies, Inc.
Table 8‐9 8.2.2.4.2 Summary Description Parameters Description Connected Displays the number of Remote Module’s connected to the ADX‐RACK‐ODU. Soft Fail Displays the total number of soft fail present. Hard Fail Displays the number of hard fail present on each module. Link Fail Displays the number of link fail present on each module. Not Commissioned Displays the number of non‐commissioned or commission failed module.
Uplink Common attenuator Downlink Common attenuator Uplink Optic attenuator Figure 8‐23 Optic Attenuation (Status – ODU) 8.2.2.4.5 Optic Path Status Displays the optic status for each optic path Figure 8‐24 Optic Path Status (Status – ODU) Table 8‐10 Status LD Status PD Status Normal LD fail Not Connected Normal PD fail Comm Fail or Not Connected Advanced RF Technologies, Inc.
8.2.2.5 Status – RU Hub RU‐Hub is not separate module but is integrated into the master RU. The picture of HPR Hub displayed on web based GUI is same as the picture of master RU. Figure 8‐25 Status ‐ RU Hub 8.2.2.5.1 RU Alarm Status The HPR Hub can support up to 8 remote modules. The HPR alarm status displays the alarm status of each remote module. Figure 8‐26 RU Alarm Status (Status ‐ HPR Hub) 8.2.2.5.2 RU Commissioning Status Display the Commissioning status of each Remote Module.
Table 8‐11 Description for RU Commissioning status Status Installed Status Commissioning Status 8.2.2.5.
8.2.2.6.1 Band Display the spectrum that is being used. The band column displays the bandwidth that has been used. The downlink column displays the center frequency of the used downlink band. The uplink column displays the center frequency of the used uplink band. Figure 8‐29 PCS Band Information (Status – Remote Module) 8.2.2.6.2 Power & Gain (Admin/User) Display the Downlink output, Downlink/Uplink Attenuation, and Uplink Input/output.
8.2.2.6.3 Optic Power (Master‐RU Only) Display the LD Power and PD Power of optic module inside the Master RU. Figure 8‐32 Optic Power (Status – Master HPR only) 8.2.2.6.4 Operating Status Table 8‐13 Operating Status (Status – Remote Module) Alarm System Link Fail Over Temperature RF Alarm Power Alarm Advanced RF Technologies, Inc. Severity Description Soft Fail Hard Fail / Soft Fail No communication with NMS. Temperature is higher than the threshold level for over temperature alarm.
8.2.3 Control Tab 8.2.3.1 Control – NMS Figure 8‐33 Control ‐ NMS 8.2.3.1.1 Heartbeat Time Allows the user to enable or disable SNMP traps from being sent out and also specify the Heartbeat interval. Time and date stamps of the last 2 heartbeats will be displayed in the “Last heartbeat sent out” section. Figure 8‐34 Heartbeat (Control – NMS) 8.2.3.1.
메모 [C22]: BCUH 추가 여부 검토 8.2.3.2 Control – BCU Figure 8‐37 Control – BCU 8.2.3.2.1 Manual ATT Control Figure 8‐38 Control – BCU Manual ATT Control Downlink: Allows the user to manually adjust the DL attenuation levels for each RF path. Adjusting these settings is not recommended since it will change the power ratios set by the user. Uplink: Allows the user to manually adjust the UL attenuation levels for each RF path.
8.2.3.2.2 Reboot / Factory Setting Allows the user reboot or restore factory settings of the BCU. Figure 8‐39 Control – BCU Reboot/Factory Setting 8.2.3.2.3 Alarm Setting Figure 8‐40 Control – BCU Alarm Setting Downlink Input Overload: Allows the user to specify the level at which the DL Input Overload alarm is triggered. Values range from 0 dBm to +25 dBm. Downlink Signal Low: Allows the user to specify the level at which the DL Signal Low alarm is triggered.
8.2.3.3.1 General Setting To enable any of the settings, click on the checkbox and click the Apply button.
The “UL Noise Det” button will take you to the UL Noise Detection page which will allow you to run the UL Noise Detection routine. Figure 8‐46 UL Noise Detection ‐ PCS band The Auto UL noise measurement routine can be run by clicking on the Check button. After all UL noise measurement have been taken, the levels for each UL path will be displayed and along with the difference between minimum detect level and measured detect level.
DL Output ALC Offset To set the Max output ALC Offset ‐10 ~ 0dBm 0.5dBm Administrator UL Output ALC Offset To set the Max output ALC Offset ‐20 ~ 0dBm 0.5dBm Administrator 8.2.3.3.
8.2.3.4 Control – ODU Figure 8‐49 Control – ODU 8.2.3.4.1 Optic Attenuation (Admin Only) Figure 8‐50 Optic Attenuation – ODU Advanced RF Technologies, Inc.
Table 8‐17 Description for Optic Attenuation (Control – ODU) Name Description DL/UL common ATT DL ATT UL ATT 8.2.3.4.2 Allows the user to control overall optic DL/UL path gain. Used to compensate DL optic loss. Used to compensate UL optic loss. Reboot/Factory Setting Allow the user to perform ODU reboot or ODU factory settings. Figure 8‐51 Reboot & factory Setting (Control – ODU) 8.2.3.5 Control – RH Hub Figure 8‐52 Control – RU Hub 8.2.3.5.
8.2.3.6 Control – Remote Module (Master or Slave RU) Figure 8‐54 Control – Remote Module 8.2.3.6.1 General Setting (Admin/User) (Admin) (User) Figure 8‐55 Table 8‐18 Name Downlink ALC Downlink On Uplink ALC Uplink On General Setting (Control ‐ RU) Description for General Setting (Control ‐ RU) Description Available Accounts This setting allows you to enable or disable the downlink ALC function.
8.2.3.6.2 Reboot/Factory Setting Allows the user to Reboot or restore Factory Settings on the remote module. Figure 8‐56 Reboot & factory Setting (Control ‐ RU) 8.2.3.6.3 Optic Setting (Only Master RU) (Admin Only) Figure 8‐57 Optic Setting (Control ‐ RU) Table 8‐19 Name Description Downlink Optic Atten PD Power LD Power 8.2.3.6.
Table 8‐20 Name Description for Manual Atten Control (Control ‐ RU) Description Range Default Available Accounts threshold Downlink Atten Allows the user to specify how much attenuation to use. 0 ~ 30dB 30dB Administrator, User Uplink Atten DL Output ALC Level UL Output ALC Level Allows the user to specify how much attenuation to use. The remote module will prevent the downlink output power from exceeding the specified value.
8.2.4 Install Tab 8.2.4.1 Install – NMS Figure 8‐60 Install ‐ NMS 8.2.4.1.1 HE Commissioning Status Figure 8‐61 HE Commissioning Status (Install – NMS) Table 8‐21 Description for HE Commissioning Status (Install – NMS) Status Installed Status Commissioning Status Display Description Physically Installed Text is black Physically Not‐Installed Success Fail or not commissioned Text is gray Green Advanced RF Technologies, Inc.
8.2.4.1.2 SNMP Figure 8‐62 SNMP (Install – NMS) The SNMP section allows you to specify the Site ID and Manager IP. The Site‐ID is the code that is used to identify a particular module. The Manager IP field is where the user inputs the IP address of the NOC system that is being used to monitor the SNMP traps. 8.2.4.1.3 Location This section allows the user to input the latitude and the longitude of the repeater.
This section allows the user to save the description of NMS. Figure 8‐65 Description (Install – NMS) 8.2.4.1.6 SNMP Agent False Alarm Test This section allows the user to generate both soft and hard fail alarms. After alarms are generated, the NOC can poll the ADX to see if alarms are present. All alarms generated during this test are false alarms. Figure 8‐66 SNMP Agent False Alarm Test (Install – NMS) 8.2.4.1.
8.2.4.1.8 Date & Time This section allows the user to specify the current date and time. Figure 8‐68 Date & Time Setting (Install – NMS) 8.2.4.2 Install – BCU Figure 8‐69 Install – BCU Advanced RF Technologies, Inc.
8.2.4.2.1 BCU Commissioning Figure 8‐70 Install – BCU Commissioning 8.2.4.2.2 Current DL Input Level: DL Input Commissioning Level: Targeted DL Output Power Ratio: Commissioning Progress: Previous DL Commissioning Level: Last Commissioning Date: Last Commissioning Time: Description Figure 8‐71 Install – BCU Description BCU: This section allows the user to set the description of BCU. Path A/B/C: Allows the user to specify a name for each RF path.
Figure 8‐72 Install ‐ RFU Advanced RF Technologies, Inc.
8.2.4.3.1 RFU Commissioning This section allows the user to perform RFU commission. To perform RFU commissioning, select a DL Input Commissioning Level from the dropdown menu and click Apply. The commissioning progress is displayed on the Commissioning Progress bar. Any errors, warnings, and messages will appear via a popup window. Please refer to the ADX Installation Guide to determine the proper RFU commissioning levels. Figure 8‐73 RFU Commissioning (Install – RFU) 8.2.4.3.
Figure 8‐76 Optic control (Control – ODU) Table 8‐22 Description for Optic control (Control – ODU) Display & Control Description Optic loss is less than 5dBo Optic loss is more than 5dBo Not connected to a RU No optic loss compensation is needed. Optic loss compensation is needed. Not connected to a RU 8.2.4.4.2 Description This section allows the user to save the description of ODU. Figure 8‐77 Description (Install – ODU) 8.2.4.5 Install – HPR Hub Advanced RF Technologies, Inc.
Figure 8‐78 Install‐RU Hub 8.2.4.5.1 RU Commissioning Status Figure 8‐79 RU Commissioning Status (Install‐RU Hub) Table 8‐23 Description for HPR Commissioning status Status Installed Status Commissioning Status 8.2.4.5.2 Display Physically Installed Physically Not‐Installed Success Fail or not commissioned Description This section allows the user to save the description of HPR Hub. Figure 8‐80 Description (Install‐RU Hub) 8.2.4.
Figure 8‐81 Install‐Remote Module 8.2.4.6.1 RU Output Commissioning This section allows the user to perform HPR commission. To perform HPR commission, select a DL Output Commissioning Level from the dropdown menu and then click Apply. The commissioning progress is displayed on the Commissioning Progress bar. Any errors, warnings, and messages will appear via a popup window. Figure 8‐82 RU Output Commissioning (Install‐RU) Advanced RF Technologies, Inc.
8.2.4.6.2 Description This section allows the user to save the description of remote module. Figure 8‐83 Description (Install‐Remote Module) 8.2.5 System The System tab allows the user to perform firmware updates, upload closeout packages, view any changes to the system, backup existing configuration, and add/remove user accounts, and change the login credentials of the Administrator. 8.2.5.1 System: Account 8.2.5.1.
8.2.5.1.3 System: Account ‐ Change Password The Change Password section allows the current user who is logged into the system to change their login credentials. Figure 8‐86 Change Password 8.2.5.2 System: Logs 8.2.5.2.1 System: Logs ‐ Event Log This section displays system events that have taken place. The Event Log displays who has made the changes, the time and date of when the event took place, and what changes were made to the system.
8.2.5.2.2 System: Logs ‐ User Log This section tracks user activity within the system. The User Log displays who has made the changes, the time and date of when the event took place, and what changes were made to the system.
Figure 8‐90 Message after System update is complete 8.2.5.4 System: System Information 8.2.5.4.1 System: System Information System Information Check The System Information Check button will check the ADX configuation and report possible discrepancies. System Information This section displays the general system information of the ADX DAS. Figure 8‐91 System Information Advanced RF Technologies, Inc.
System Notification This section is displayed only when the following conditions are present: ‐ When multiple remote modules with same frequency band exist in a RU. ‐ When the remote module does not match with the RFU being used. Figure 8‐92 System Notification BOM BOM displays all parts that are connected to the ADX‐H‐NMS. The BOM can be downloaded as a CSV file by clicking the ‘Download’ button at the bottom right. Figure 8‐93 Bill of material 8.2.5.
Settings Backup Clicking the Backup will create a temporary backup file stored inside of the ADX. Once the file is created, it will need to be downloaded to a computer. A download button will appear after the backup file has been created. If the ADX is power cycled or rebooted, then the temporary backup file will be lost. We recommend downloading the backup file immediately after it has been created. Click on the Download button to download the backup file.
Restore function can be used to restore the saved settings from the backup file. Once the backup file is loaded, the tree in the figure below will appear. Check the boxes of the modules that you would like to restore and then click the “Restore” button at the bottom on this section. We recommend creating a new backup file if adding or removing modules from the ADX. Discrepancies between the backup file and the existing tree could cause restore errors. Figure 8‐96 Setting Restore 8.2.5.
SNMP V3 This section allows the user to add accounts for SNMP v3. Figure 8‐98 SNMP V3 8.2.5.7 System: Closeout Package The closeout package section will allow the user to upload documents to the ADX‐H‐NMS. The maximum file size for each upload is limited to 10 MB. The total amount of space available for uploading document is 100 MB. Please do not use this section as the primary storage location of your documents. Documents may become unavailable if the system goes down.
8.2.6 Help If an internet connection is available, clicking on the Help Tab will redirect the user to our Technical Support page. Figure 8‐101 Help 8.2.7 Logout Clicking the Logout button will log the current user off the system. 8.3 Guest Mode When logging into the system as a guest, the guest will only have read‐only privileges and will not be able to make any changes to the system. Advanced RF Technologies, Inc.
9. SYSTEM‐WIDE SPECIFICATION (TO BE CONNECTED TO HE VIA OPTIC LINE) 700LTE/CELL/SMR800 Specifications. 메모 [H23]: SMR800 의 경우 FCC 인증에서 제외함. ( ACP 문제점) 700F Lower ABC Downlink Upper C Frequency Lower ABC Uplink Upper C Gain 869-894MHz 851~869MHz 824-849MHz 806~824MHz 25MHz 18MHz 0~25dBm 0~25dBm 746-757MHz 698-716MHz 776-787MHz (Lower ABC + Upper C) DL Input Range SMR800 728-746MHz 16+11MHz Support Band Width CELL 0~25dBm D/L 18~43dB, 0.5dB step, ATT range: 0~25dB U/L -5~30dB, 0.
NOTE: Industry Canada Cellular band 20dB nominal band is from X MHz to Y MHz for Downlink and from X MHz to Y MHz for Uplink. 2. PCS/AWS/BRS Specifications. PCS AWS BRS Downlink 1930~1995MHz 2110~2155 MHz Uplink 1850~1915MHz 1710~1755 MHz 65MHz 45MHz Frequency 2496~2690 MHz Support Band Width 194MHz +12~37dBm DL Input Range 0~25dBm (Medium Mode) 0~25dBm -15~12dBm (Low Mode) Gain D/L 21~46dB, 0.5dB step, ATT range: 0~25dB U/L -5~30dB, 0.
NOTE: Industry Canada Cellular band 20dB nominal band is from X MHz to Y MHz for Downlink and from X MHz to Y MHz for Uplink. 메모 [H26]: 해당 제품의 SPEC 의 경우 3. SMR900 Specifications. 향후 추가될 제품의 SPEC 임. SMR9000+Paging Frequency Downlink 929~942MHz Uplink 896~903MHz DL:13MHz, Support Band Width UL: 7MHz DL Input Range Gain 0~25dBm Range Range Attenuation D/L 18~43dB, 0.5dB step, ATT range: 0~25dB U/L -5~30dB, 0.
NOTE: Industry Canada Cellular band 20dB nominal band is from X MHz to Y MHz for Downlink and from X MHz to Y MHz for Uplink. 메모 [C28]: 주파수 수정 2015.07.28 4. WCS Specifications. WCS Frequency Downlink 2305-2315MHz Uplink 2350-2360MHz Support Band Width Gain Comments 10MHz +12~37dBm(Medium) DL Input Range -15~12dBm(Low) Range Range Attenuation D/L 19.8~44.8dB, 0.5dB step, ATT range: 0~25dB U/L -5~30dB, 0.
NOTE: Industry Canada Cellular band 20dB nominal band is from X MHz to Y MHz for Downlink and from X MHz to Y MHz for Uplink. 10. MECHANICAL DRAWING Figure 10‐1 HE Drawing Advanced RF Technologies, Inc.
메모 [H30]: 6band 로 모델명 수정필요함 Figure 10‐2 HPR Drawing Advanced RF Technologies, Inc.