NEC of America 5816 5.8 GHz Unlicensed Digital Microwave Radio User Manual Manual Volume I
NEC Corporation of America 5.8 GHz Unlicensed Digital Microwave Radio Manual Volume I
Contents
Manual Volume I
R01—304820-051E 031020 5.3 GHZ 15128150 MB PDH DlGlTAL MECROWAVE RADIO SYSTEM NLite L (PDH 1+Ol11‘1 SYSTEM) SECHONI DESCHPHON CONTENTS CONTENTS TITLE PAGE 1, GENERAL ...................... 1.1 2. SYSTEM DESCRIPTION mm- 2.1 System Configuration "- 2.2 System Performance .... 2.3 RF Channel Plan ........ 2.4 Alarm and Control-"mun” 2-1 2-1 2-6 2-1 0 -........................... 2.10 2.4.1 Alarm Indication and Reporting ------------"--~--—~-- 2-10 2.4.2 Psriormance Monitoring/Metering Data Reporting- 2.4.3 Automatic Transmitter Power Contra z_4_4 Loophack Central ........................... 2.4.5 NetworkManagement(Optional) (released afler Jan., 2004) 2.5 Prolecfion Swltchlng mm- 2.5.1 Swltchlng Centre 2.8 Power Suppl mu 3. SUBSYSTEM DESCREPTION INDOOR UNlT '- M»- 3.1 Composlticn -- 3.2 Funcflonal Operation u.......... 2-13 2-13 "mum-m. 2.17 3.2.1 ModulatorSection-mm-mnm ............................. 3.5 3.2.2 Demodulatcr Section mum-- .--.-.-...................... 3.5 CONTENTS TRP UNIT ununuuuuu-nu 3.3 3.4 3.4.1 3.4.2 ROl—SOAEZG TITLE PAGE "mu-«n... ................... 3.5 Compnifionumuun nm-Iml-m- "mam“... 3.5 Functional Op-raflon mum-mu Transmitter Section n-luonnuuuunu'uunmunun-u n. 3.7 Racelver 59amn...........-.........m-.m-mum-mum.- 3.7 ROI-504520 GENERAL 1 GENERAL This section provides descriptive information on the 5.8 GHz 15/28/45 MB digital microwave radio system for the plesiochronous digital hierarchy (PDH). The 5.8 GHz 15/28/50 MB digital microwave radio system is designed to transmitting DS-l or DS-3 level signals. It operates in the 5.8 GHz radio frequency hand using the 32 QAM or 128 QAM Quadrature Amplitude Modulation (QAM) method and has a transmission capacity of 8 x 11544 MB or 16 x 1.544 MB, for 1 x D53 64 QAM is utilized. Included herein are system description and subsystem description. GENERAL ROI-804820 (This page is intentionally lefi. blank.) ROI-504820 SYSTEM DESCRIPTiON 2. SYSTEM DESCREPTlON can; s The system description outlines the system configuration. system performance, RF channel plan, alarm and control, protection switching, and power supply, 2.1 System Configuration The system consists of the Modulator-Demodulator (MDP), Transmitter- Receiver (TRP) and the Antenna (see Fig. 2-1 to Fig 2-2), The MDP twes are as follows: 0 MDP-lSMBST-lA: 8 x 1.5 MB, Fixed bit rate type - MDP-ZSMB7TAIA: 16 x 1.5 MB, Fixed bit rate type - MDP-SOMBéT—lB: 1 x 45 MB, Fixed bit rate type The 5.8 GHz 15/28/50 MB microwave radio system is a l-hop (paint-to—point) system between two terminal stations, and is configured in the HI (Hot Standby) or HO (Expandable) system. i: Sage“, naoo’ ° 6 Ezfi W 6T <0 O I‘ @%© L [Ea , MDP-lSMB5T-1A(B x15 MB FIXED BiT RATE TYPE) for 1+1 SYSTEM f @ " z» w “4 (D _ ©¢© mel‘lfi rm “mam m r“ m |_; o (D (9 EDGE Em” C??? %3 mm (D c: 4 Dm G i: a 5” C3,“ 3“ Elmer-El may MDP-ZSMB7T-1A(l5 x 1.5 MB FIXED BIT RATE TYPE) for 1+] SYSTEM Fig. 2-1 Outline ofMDP ROI-504820 SYSTEM DESCRIPTION 5.8 GHZ BAND TRP Fig‘ 2-2 Outline of TRF ROISMBZD SYSTEM DESCRIPTION 5655: xusm Ewugm 5230.3: | £32“ 0:5: gal-EEG. 3.59 a.“ .mE all... at; Elisa“ x55 £35. as $5325; 1282. B; «is? Q gazing-es. (5.52.9 GE 2568351}? own (Bail—7; as"! ea ma isfinxii! ES: nizfiunefi £883 15! firiuaixgsln” his 3315 as. 3 518” 58 iflfirigiin‘ nix Eiu 1.3. 5. El!" t: % : ss, EAI. as, t E. .__ , J. ._S : ? y i . 11 ‘ L fig-6:5 z? .Emusflubz. J 52; m. Alilv E:- 3 SEE raisin: in .2 5p SYSTEM DESCRIPTION ROI-804520 EEmnE saga Esim E2255 83552293: | Esmam flung $5205 355 in .m_.._ .§=§.EE§~§§§§‘ 1' gmflziifi~£§§§h1 6:2 E5. 5... E. E?» 555” so 3. 8.) 4mm Essie-negsxéan k» “R Euniimin can! 5.3823! 58; . 5838 Egg-xgg. SE 53,5.” 2 58 §5~§§EE mat _...,_.51§u5” E E. 553.5 . 53, 523,32 in V 5. L1» SYSTEM DESCRIPTION 2.2 System Performance The system performance characteristics of the 10.5 GHz 15/28 MB digital microwave radio system are listed in Table 2-2. Table 2-1 System Performance (Typical Value) A. Major Specification Transmission Signal Transmission Capacity Modulation Demodulation Forward Error Correction (FEC) Equalizer Data Interface Impedance 8 x DSl/16 x DSl System 1 x D53 System Service Channel OEOW - RS-232C(*1) . V.11(*l) D51 &D53 8 x 1.544 Mbps (8 x DSl)/ 16x1.544Mbps(16xDSl)/ 1x 441736 Mbp/s (I x D53) 32 QAM (for s x D51)/ 123 QAM (for 16 x DSI)/ 64 QAM (for l xDSS) Coherent detection MLCM/RS DFE BSZS or AMI for D5] (ANSI T1, 102) 100 ahms,ba1anced 75 ohms, unbalanced ICH lCH 2CH ROI-504820 ROI-504820 SYSTEM DESCRIPTlON Table 2-1 System Performance (Typical Value) (Cont’d) TX Power Control ATPC/MTPC 0 to 23 dB (1 dB step) (8 x 1351) 0 to 20 dB (1 dB step) (16 xDSl & l xDS3)) TX Switching System Mute output power of the reserve TRP (HS/HS) in split system. RX Switching System Hnless swnch Switching Range Delay Equalization Range Switching Criteria Loopback Function Perfonnance Monitoring (* 1) Measurement Alarm Output Housekeeping Alarms (* l) Dynamic more than 447250 us in total Remote and Auto (F ASYNC ALM, LOW BER ALM) LB 1 (Far End, CH by CH basis) L132 (Near End, CH by CH basis) IF (MODEM loop back) BEE, ES, SES, UAS, OFS (total) TX power level, RSL, BER Relay contact (F arm—C); 7 items (4 alarm items mapping allowed) Relay contact (Form-C) 4 Items Photo-coupler 6 items SYSTEM DESCRIPTION ROI-504820 Table 2.1 System Performance (Conx’d) (Typical Value) Bi System Parameter for Split Type S ecificati on Condition/Remarks Transmission Capacities 8/16 X D51 Transmit Power 5.8 GHz +25 dBm Typical System Gain 5-8 GHZ 105 dB @10*°, Guarantee —3 dB MDP—TRP IFL Cable Length (Split type) 200 m RG~14/U, RG-224/U or Equivalent Ambient Temperature MDP 0°C to +50°C Guarantee TRP 733°C to +50°C —i 0°C to +55°C Workable ——40°C to +55°C —40° C to +70“ C Storage mama H‘m‘idny Less than 90°/a at 50°C (Non-condensing) Power Supply Voltage 36 to 60 V DC Input Floating ROI~SD4820 SYSTEM DESCRIPTION Table 2-1 System Performance (Cont’d) (Typical Value) C. OVERALL MDP-TRP Interconnection Cable l/F Line Cable (Type and Maximum Cable Length) Primary Voltage (Safety Extra-Low Voltage (SEL V)) Power Consumption (MDP + TRP) Dimension MD? TRP TRP Temperature Range Guaranteed Operation MDP TRP Workable Operation MDP TRP Transport and Storage MDP TRP Relative Humidity Altitude Single coaxial cable, 50 ohms impedance - 200 m (SD-PB coaxial cable or equivalent) 0 300 m (SD-FE coaxial cable or equivalent) 0 350 m HOD-FE coaxial cable or equivalent) 0 450 m (lZD—FB coaxial cable or equivalent) - —48 V DC (_36 to "60 V) or +48 V DC (+36 to +50 V) 110Worless 482 mm (W) x159 mm (H) x 300 mm (D) 240 mm (W) x 243 mm (H) x124 mm (D) Approx 10 kg, H0 system (Including optional module) Approx. 14 kg, l+1 system (Including optional module) Approx. 5 kg 0°C to +50°C 733°C to +50°C —10°C to +55°C 440°C to +55°C 40°C to +70°C —-40°C to +70°C Less than 90% at 50°C (Non-condensing) Up to 4,000 m SYSTEM DESCRIPTION Rel-504520 2.3 RF Channel Plan Radio frequencies for the NLite L 5.8 61-12 is as follows: - FCC 10.5 6141 Band : 5725 Mhz to 5850 Mhz The actual TX frequency of the TRP should be within the TX radio frequency band of the RF CKT in the TRP and is entered using the local craft terminal (LCT). The corresponding RX frequency is automatically set afier the TX frequency is entered. For details, refer to Appendix in Description section, The frequency spacing between adjacent channels should be taken as following system. - 8 x D51 system : 3.75 MHz - 16xDSl system:5MHz . l xDSS system: 10 MHz 2.4 Alarm and Control The alarm and control system is shown in Fig. 2—6. The functions of the alarm and control circuit are as follows: 0 Alarm indication and reporting 0 Performance monitoring/metering data reporting 0 Automatic transmitter power control - Loophack control t Network Management (Optional) 2.4.1 Alarm indication and Reporting Alarm indication and repom’ng functions are provided with the MDP. Summary alarm indicators using LED’s are provided for the TRP and MDP, separately. When the TRP is detected any alarm by the alarm detector in the TR? are sent to the CTRL module in the MDP. This causes the TRP alarm indicator on the MDP front panel to turn on. Similarly, any MDP related alarms that are detected will cause the MDP alarm indicator on the MDP fiont panel to turn on. External reporting of alarms is also provided through closed relay contacts accessible via the front panel interface (see Table 2~3). ROI-804820 SYSTEM DESCRIPTION F222 ..z.<2 25 2.5.2.5 55? . 35.5”. t. “5.3. . NE. 8. .2_..8..=_=_... p< . 355.5. 5 5:23.22... 3.28 2.52.0. u... 6.2... a... 5 £5... 35551... 2 .. 2855? “e E? N 2..< LE ... _ 2..< 225“ N 2.< Err... _ 2..< E 2 2 s: N S. E 22. 5: _ az an. m, E2 25 5... as 5.22. 5.55.55 21 £56 N5 . 2..< .N..< N 2..< Eta . 2..< b: 2..< 5; N oz 5 2..< 5? . az 8.8.5. m. 52.68 ii... 56 “2.523 2..< 92 23233 1.5. N 2..< SEE. 2..< i... 2..< 5... N52 5 2..< 5: ..oz 13. 5.2.2. 5.2. “38.2... is. an... 3233. 55 b. 2 < qua... xx NE . 2..< SE. x... N 2..< 5:5 . 2 2 s... 2..< it Ndz E... E2 is. 2.53 2.2. a. x.. 55 u... §N.5 . < Es. x. N 2..< Er... _ 22 5: 2 5.52: 52.2 Eta: 1.59. 22. me N NEH...» 5.5.8.33352 5:9. 5. gig; USE 2? NEE x. 2..< 9.5. m... N 2..< E2 2... . 2..< E2 2..< E2 N a 2.- 2..< E2 _ 0 SE... afiz. MSW 2.1.2.5. 5.5. “22... 5.3... 5. ”ma z<.. £5.20. ufiz. N. 3 m9. 2: 8.1.7.2 E 2..< xx 9.5: 2..< VC Viz N 2..< E2 2... _ s:< E 2..< E2 N5 25 2..< E2 ..= 2.2... cave... "55.2 5» 2.3. 5,2 8.5. z.<2 mo. 2.2 9:2. z.< 2325 z. 22 N 2..< E2 25. 2..< E2 2..< E2 N _. E.» 2..< E21... E“. w. a...“ 2.2. $26.53 25...“ 52 ES: 52 “9 2m . 8.2. 222 2..< 9:2. 5. N 2..< E2 25 . 2..< E2 2 .< E2 N cz 1...» 2..< 52 2.2 E. E... is; is... a as.“ via... a...” 5. 23m 52 2..< xx ufiz 2..< y... z. x. N 2..< E2 2.2 2..< E2 2..< E2 Na 25 2..< E2 2 23:1...“ 52.3... “2m 5 15am E2 2..< 5 BE N 2..< m. 8 . 2..< m N 2..< E2 5 _ 2..< Ne 2..< E2 N sz 5 2..< E2 . u 2:5 25.2. 3.8 undo 2.8 and: >....Ew 525". N 21 in... . 2..< NM... Nb... 5. N 2..< 2mm 5 . 2..< 25. N 2..< 502 L.- _ 2..< 82 N 2..< E2 5. 2..< E2 2..< E2 N 02 s 2..< E2 32 25.2 355... 2.302 2202 N 2..< Nam 26.19.22 Ea 35 N 2..< 2.5 5 . 2..< 2 a N 2..< NE. Eu Ce _ 2..< 5m :o.. N 2..< 2Es _ 2.< 2m... . 2:3 :§=._.._.:EZ_§_ 2..< 5m 25. 2... E2 N5 5 2..< E221 f: x N. 2.5 an... 52. as; M. NH. 2..< «mm mm... N19 5 _ ..o.. N 2..< E2 5 _ 2..< E2 2..< E2 N oz 5 2? E2 . 3. so. ._§__§_.u_.r 2.5 E. N 2..< E2 5 _ 2..< E2 2..< E2 Na: 5 2? E2 1“ 233 £23... 552. 5.55555 2..< Eun2 N 2? 2mm; . 2 < 2mm. N 2..< E2 5 . 21 E2 2..< E2 N a s 2..< E2 _ o 31:29. Ea... 2..< 23 N 2 2 9.2... . 2 2 cc: N 2.< E2 5. 2..< E 25.9.2. 5-2 32.8. 2: 22: 522 E2 _ 3 E2 5. 555.2: mm. . $5 52 No Em x...“ 153.3. E... 32250 SEE mirage”. E; cam—3:2: E..u.< «é EN...» 2:32 95-2... 2.62 2..< 002 AN 522.02 22: n SYSTEM DESCRIPTION ROI-504320 EmEmE xusm 3:26:5— _2«=oo “Eu E..m.< "AN 9m «30m rqu 3&9. 33682» HUQ 22 An E». 3 53 Gina ES?- mmmfi an N «EEQE fiatkfifiu .~5§.:RQ a 456sz ii Lfiq 9: L3 2: L3 xxx L|o¢. |.|¢u7 J|wu 0) ENHw>m pwfl xmfi \ fwn x m k 53 «mm 29 wfiééé ,~ 22 N53: 5... flag. am 51 amt. s: 3: , saumm m m 24( mm 2 s:( mm fi fi fi fi \§ziiff fl fl 52:55 88 13mm : 2 33° in 32 $4555 5:55 2: 5:52; fizfimgssxi 55m§i6x§ 5 v 2 Eéfi 425? SEQ; r: .. : .. 5055.8 ll 5:5 an _ ROIsOABzo SYSTEM DESCRIPTlON 2.4.2 Performance Monitoring/Metering Data Reporting To monitor the transmission quality, the equipment is provided with the performance monitoring and the metering functions. The CTRL module polls the difi'erent modules and gathers PM/Metering information. A “invalid” displayed in the PM results screen indicates that the value is illegal. A “MAINT” is displayed if the PM results are obtained while the equipment is in maintenance mode. When the equipment clock setting is changed or the power is turned on/oif, the PM value is judged to be invalid. The monitoring items are as follows: Performance Monitor (released afier Dec, 2003) - Out of Frame Second (OFS) - Background Block Error (BBB) Errored Seconds (ES) Severely Errored Seconds (SES) Unavailable Second (UAS) - TX POWER - RX LEVEL ' TRP PS MON ' BER (Bit Error Rate) 2.4.3 Automatic Transmitter Power Control The automatic transmit power control (ATPC) fin-lotion automatically varies the TX output power according to path conditions. in the SHF and EHF hand, fading exerts heavy influences on propagation, causing the receive signal level at the opposite station to vary. The ATPC function operates by controlling the transmit output power of the opposite station according to the variation of the received signal level at the local station. ATPC provides the following advantages: ~ Improvement in up fading characteristics - Improvement in residual BER characteristics ' Reduction of interference to inn-a system - Reduction ofinterference to inter system ROI-504820 TRANSMlTTING snnon Fig. MODE I POWER CTRL SUBSYSTEM DESCRIPTION A functional block diagram ofthe ATPC operation is shown in Fig. 2-6. ATPC improves the BER characteristics under adverse changes in climatic conditions and reduces the possibility of interference, To implement ATPC, the received level (RX LEV) is detected by the receiver (RX) and passed on to the CPU on the CTRL circuit of the MODEM module, The CPU then determines whether the transmit output power needs to be controlled. This is based on the transmit output power, the minimum and maximum values of the output control range (ATPC range), ATPC is relevant for the receiving threshold (RX Threshold) level that were previously specified value using the LCT or PNMTi A control signal (POWER CTRL), whose function is to maintain the RX signal by lowering or raising the TX output power of the opposite station, is generated by the MODEM module through the CPU circuit. This control sigtal is based on the result of comparison between the current receiver input level and the preset receiving threshold level. This control signal is sent to the opposite station to control its transmit output power. At the opposite station, this control signal is detected by the MODEM module. It the MODEM module, in accordance with this control signal, produces a control that will either raise, lower or maintain the current TX output power. RECEMNGSIAIJQN. 2-4 ATPC, Functlonal BLock Diagram ROI-804520 SYSTEM DESCRIPTION The ATPC Control System of the NLite L transmits the information on the receiving level to the opposite station and controls the transmission level of its local station in accordance with the receiving level of the opposite station. Transmission level control can be used not. only for setting the same operation (ATPC-ATPC) between local station and opposite station but also for operation in combination of stations with different operation (MTPC—ATPC, ATPC-MTPC) between own station and opposite station. The station set in MTPC mode is not controlled by the information from opposite station but is fixed in its transmitting output level. Even if the station is set in the MTPC mode, the opposite station is likely to be set in the ATPC mode. Therefore, setting the RX Threshold (Receiving threshold level) is required for controlling the transmission level of the opposite station. Between the stations that are respectively set in the MTPC mode, however, the setting is disabled. The following is an example of operation between stations set in MTPC- ATPC mode. 5 ATIQN A § ATIQN B (Z; NLIte L NLite L MTPC ATPC (RX Threshold: —50 dBm) The transmitting level of station E is controlled so that the receiving level of station A in the above figure reaches the RX Threshold set level (—50 65m) set in station A. This method is used in station A for reducing the level of interference to other route. As station A is set in the MTPC mode, the transmitting level is kept unchanged. Then an example of using MTPC-ATPC is shown below As shown in the figure, in the master station commimicating with many substations, waves gather from substations possibly causing interferences. Therefore, substations must be set in the ATPC mode to minimize the diffraction (interference) to other routes while reducing the receiving levels from individual substations to the minimum In substations, there is little possibility of occurring interferences; therefore, the master station is set in the MTPC mode to permit transmission at a constant level. SYSTEM DESCRIPTION ROI-504820 (ATPC) BSTATION 1 [HZ—J- Tfiflifié <'®Z-}E (ATPC) T TIO (ATPC) §y§§TAT|gu 5 3 SUBSTATION 2 &// ,%> (ATPC) (ATPC) s TATtO guBSTAT gm 3 ® : Diffractlcn to fiber route. ROI-804520 SYSTEM DESCRIPTION 2.4.4 Loopback Control The lunpbflck fimction is provided fur checking the sysoem quality during maintenance and/or tn quickly isolate a fault lacstion. The control is performed by the LCT, the mm or the PNMS. The following types uf loopback are provided: ~ DSl near-end loopback (DSl LB!) at the CTRL mudule ((a) in Fig. 24). - Main D81 far-end loopback (DSI LBZ) at the CTRL module (03) in Fig. 2.7). - E‘ loopback (IF-LB) at the MODEM module ((c) in Fig. 2-7). Notes: 1. While the IF loopback is in execution, monitoring of the opposite and the subsequent stations are disabled on the PNW and PNMT 2. Loopback control will inter-mp: the radio 1in connection. TRANSMITnfl gun mm MDP TRF TR? MDP PDH E/u SPEE'J SPEED ma ANALYZER chVH cow M0“ TX RX fl coNv OONV v‘ 1°) (c) ._. (b) PDH ws spear: EM ANALVZER cowl“ cow 55” RX TX M0“ E‘— CTRL M_QDEM M105 QIEL GTRL Note: Reverse direction is the same ax abave, Fig. 2-7 Loopback Locatlon SYSTEM DESCRIPTION ROI-304820 2.4.5 Network Management (Optional) (released after Jan., 2004) The Network Management System (NMS) configuration is shown in Fig. 2-8. The pasolink network management system (PNMS) is connected to the PNMS Vii/LAN connector of the MDP located at the designated maintenance center while the pasolink network management terminal (PNMT) is connected to the PNMT connector on the MDP of remote stations The FNMT/PNMS provides monitoring and control of the actual microwave link status and its associated NLile L equipment Status information form and control signals in remote stations are transmitted using one of the SC channels. Note: This SC channel is multiplexed on the main signal for subsequent transmission to the opposite station. (f the IF Inopback is executed the SC channels of the station under maintenance will also be looped baCk. thereby making it impossible to monitor or 00an the opposite and the subsequent stations For derailed information, refer to the related PNMS or PNMT manual __<41’>_‘_ SC NLite L ¢ eeeeeeeeeeee » NLiia L PNMS V.11ILAN PNMT v CONNECTOR v CONNECTOR PNMT PNMS: Pasclink Network Management System PNMT: Pasolink Network Management Terminal Fig. 2-8 Network Mun-gomont Syshm Roi-304820 SYSTEM DESCRIPTION 2.5 Protection Switching Protection switching is provided for the TX and RX sections in the Hot Standby (HS) system and is performed by automatic control and manual control. The TX protection switching is performed by the mute control on the No.1 and No] channel TRPs at the transmitting end of the Hot Standby system in the split type. The RX protection switching is performed by the Hitless Switch (l-IL SW)“ onthe SW UNIT nfthe MDP at the receiving end ofthe Hot Standby system. Note: The killers switching of Main DSI data is performed when the detected BER exceedr the internally preset value (3 x 107) in automatic switching mode. When switching is performed by manual control or by an alarm event, hit is occurred by switching. The hitless switching is not applied for DSC signals The manual control should be performed in maintenance status. This is because automatic switching is implemented by hardware logic and manual switching is implemented by software logic. That is, automatic switching and manual switching are completely independent and different switching conditions. Then, note that when the operator reverts to automatic switching alter performing manual switching, the channel will be re-selected by the automatic switch connol. 2.5.1 Switching Control (a) TX Switching The TX switching is performed by manual or automatic control. The manual control is executed by operator tom the LCT in maintenance status. The automatic switching that is initiated by detection of a failure in the n-ansmit section of the MDP or TRP. While TX switching, either initiated manually or automatically, may cause a instantaneous interruption of the transmission. Automatic and manual TX switching have the following operational features: - Manual switching: Selects TRP of either No,l or No.2 even if TRP is alarm status. The manual switching control has priotity over the automatic switching control. - Automatic switching: The switching is performed when the modulator alarm is detected in the MDP or when the TX IF input alarm, TX power alarm or APC alarm is detected in the TRP. SYSTEM DESCRIPTION RDISMBZD In the automatic switching mode, No.1 channel can be given Priority or Non-priority. Under the priority mode, when switchover has been performed from No.1 CH to No.2 CH caused by No.1 CH nlami, reversal switchover is performed automatically from No.2 CH to No.1 CH when alarm condition of the No.1 is restored. Under the Nompriority mode, the switchover is performed alternately fi'fim No.1 CH to No.2 CH or vice versa according to the alarm status. The TX switching condition is shown on the LCT and by the TXl and TX2 STATUS indicators on the SW UNIT. (h) RX Switching The RX switching is performed by the HI. SW on the SW UNIT of the NDDP in the Hot Standby system. The RX switching is performed by manual or automatic control. The manual control is executed by operator from the LCT in maintenance status. The automatic switching that is initiated by detection of a failure in the receive section of the MDP or TRP. The switching priority and switching conditions for automatic and manual switching are identical to those of TX switching. The switching condition is shown on the LCT and by the RX] and RX2 STATUS indicators on the SW UNIT. ROI-504820 SYSTEM DESCRIPTION 2.6 Power Supply The power supply system block diagram is shown in Fig 2-9. The DC-DC CONV module on the MDP produces regulated +53 and +3.6 V DC power from 148/124 V DC input power for the component modules in the MIDP. Also, this module produces a regulated —43 V DC power from the —48 V DC input power for the TRP. The power to the TRP is supplied through the coaxial cable which is also used for the IF and other signals. The DC-DC CONV module of the TRP produces +7/+9/+10 and —15 V DC power for the component modules from the -43 V DC power supplied from the MDP. MDP TRP (No.1 cu) , T oan‘ch h‘ _._. sew IF m coma SEPéK'ISME l; g‘m sew IF our? FlL J ‘f . um I Do ”77“ fig . lNPUT ‘_(_L. 43V (JAM . Dc—DC —- wl+91+10V 45 w MoDEM l 4’ conv _- -15V 1 +4sv r ‘ »5.av L,W._._,.7>.J mom [ ,,,,,,,,,,,,,,,,,,,,, “m1 r A _ _ ENEEQHL _ j +5,3V ,, . ¢3.6v || 1 (SAMEASABQVE) - ~ (SAME ASABOVE) ‘ H l , , A _ ..l L , , , , A J Note: The common (CTRL and LAN/DSC) moduIe: are supplied DC powerfinm the DC—DC CONV modules of both No. I and No 2 m protect the system. Fig. 2-9 Power Supply System Block Diagram SYSTEM DESCRIPTION rim-304820 (This page is intentionally lefi blank) ROI-804820 SUBSYSTEM DESCRIPTION 3. SUBSYSTEM DESCRIPTION Li Wmmflflmwfi ffiflm Described herein are composition and functional operation of each module of the MDP and (he TRP. INDOOR UNIT 3.1 Composition The following equipment are composed of appropriate plug-in units as listed in Table 3-1. The component unit/modules are arranged on a shelf as shown in Fig. 3-1. Table 3-1 MDP Equlpm-m m Equlpmem Name Capaelty Modulation H0763A MDP»15MBST-1A 3 X D5! 32 QAM 1107638 MDP~28MB7T>1A 16 x D51 128 QAM - MDP-l SMBST-IA: 8 X DSl, Fixed bil rate type ' MDP-28MB7T-1A: 16 x DSl, Fixed bit rate type Tabla 3-2 MDP Component MDP-15MB5T-1A "lawman-1A (uxbsn (1enDs1) Unlt Name H0756A SW UNIT H07665 sw um H0936A MD mm N0. 1 CH 1409355 MD um H0936A MD mm No. 2 on HBDSGB MD UNIT HDDJSA cons cow optional 03) H0934A LAN mm: uplinnal m) Notes:1. x‘ : Applicable, fl zNolAppIicabIe 2. ‘Location numbers are referred to those in Fig. 3-1. 3. Supplied afier Dec, 2003. 4. Supplied in fimlre. SUBSYSTEM DESCRIPTION onu INTFC Dc-Dc QAM CONV MODEM H (TOP LAYER/BOTTOM LAYER) fl TOP VIEW FRONT MAIN BOARD 1A5M INTFC (MEDIUM LAYER) {F TOP quw FRONT ROI-804820 L eq—ifij- e\ Fig. 3-1 MDP Component Unit/Module Arrangement Natex.-I. Location numbers are referred to those in Table 3—1. 2. " For details, refer tn Note 7 of Fig. 3-3 in Chapter 3, ROI-504820 SUBSYSTEM DESCRIPTION 3.2 Functional Operation A block and level diagram of the MDP is shown in Fig. 3-2. Functional operations of the TRP are described separately for the mudulator section and demodulator section. SUBSYSTEM DESCRIPTION us! DATA IN/Ou'r PNMT Lc'r Eovw Ecwz NE1 NE2 PNMsvn wws [AN VF waur CLSTR ALM ‘ r f t 21 ‘TP 4» L]. ISMINTFC 0 cTRuCF'U MD uNlT(No.1; MD unmmu 2) " ROI-804820 No | \F iNIOUT <—~>' No.2 ; IF INIOUT Notes: 1. The recommended cable, SD-FB, has I5 dB (at 140 flab/26 dB (at 340 W2} 1sz at the maximum length 0/300 meters (Ifloflfeet). 2. For details afSC Assignment and Sub In Mfume, refer to Fig. 3.3. 3. " Narpmvldzdfor 1-H) systm‘ Fig. 3-2 MDP Block and Laval Diagram ROI-504520 SUBSYSTEM DESCRiPTION 3.2.1 Modulator Section The DSl signals received from the terminal equipment enter the 1,5M mTFC module in the SW UNIT. The 1.5M DITFC extracts the clock component from the date signal. Then the code format of DSl signal is convened from BSZS or AMI into Non-Retum-To-Zero (N'RZ) with extracted clock signal and fed to the QAM MODEM module. In the QAM MODEM module, the data signal is speed-converted into radio frame format and time slots are made. Then additional hits for the digital service channel (DSC), orderwire (OW) and supervisory (SV) signals are inserted into the time slots. Moreover, error correction FEC bits are inserted, coded and string-converted into the data signal rows for modulation The signal is then modulated with local oscillator signal into a 340 MHz IF signal, and is fed to the ODU INTFC module. In the ODU JNTFC module, the 340 MHz IF signal is multiplexed with the DC power and control signal, etc. which are fed to the TRP afler the undesired amplitude-frequency characteristics due to the IF line cable is compensated. 3.2.2 Demodulator Section TRP UNIT At the ODU INTFC module, the control signal is separated from the 140 MHz IF signal received from the TRP. 140 MHz IF signal is fed to the QAM MODEM module afler the undesired amplimdeffrequency characteristics due to the IF line cable length and the signal level are compensated. The 140 MHz IF signal from the ODU TNTFC module is demodulated at the QAM MODEM module, then regenerated to the baseband signal composed of the radio flame. Afier the detection and correction of errors that occurred through the radio link are corrected, and radio flame synchronimtion is established. Then the DSC,WS, OW and SV signals inserted in the transmitter side are extracted from the time slots The time slots for additional bits are removed, and fed to the 1.5M [NTFC module. The NRZ—coded data signal is converted into the original DSl BSZS or AMI data signal and fed to terminal equipment. The composition and functional operation of the TRP are described in this chapter. SUBSYSTEM DESCRIPTION ROI-804820 3.3 Compositlon The component modules are arranged on the shelf as shown in Fig. 3-4. INSIDE OF TRP Fig. 3-3 TRP Component Module Arrangement RDlSOABZO SUBSYSTEM DESCRIPT|ON 3.4 Functional Operation The block diagram ofthe TRP is shown in Fig. 3-5. Functional operations ofthe TRP are described separately for the transmitter section and receiver section. 3.4.1 Transmitter Section An alann/conirol signal, Engineering Orderwire (BOW) signal and DC component which are composed of the IF signal are separated through the multiplexer (ND’X) circuit. The alarm/control signal, and BOW signal are applied to the CONT module. The DC component is applied to the DC—DC CONV module to produce regulated DC voltages which are used in the TRP. The 340 MHz IF signal applied fiom the W)? is converted into the RF signal by mixing with a local signal genemted at the SYNTH module, The RF signal is fed to the BPF which eliminates undesired components caused through the IF-RF conversion. The RF signal firm: the BPF is amplified and controlled the level by the ALC and ATPC flincdon. The amplified RF signal is sent to the antenna though the BPF and circulator. 3.4.2 Receiver Section The RF signal received from the antenna is amplified lo the required level by the RF amplifier. The RF signal is converted into the 140 MHz lIF signal by mixing with a local signal generated by the SYNTH module. The 140 MHZ IF signal is AGC controlled and fed to the MDP through the MPX circuit which combines the alarm/control signal, EOW signal and monitoring signal. ——__l RF IF m/ou-r IN/OUT RF CKT (To/From MDP) SYNTH I RX LEV MON (sow INIOUT) CONT Flg. 3-4 TRP, Block Dlanram SUBSYSTEM DESCRIPTION ROI$04320 (This page is intentionally lefi blank.)
Source Exif Data:
File Type : PDF File Type Extension : pdf MIME Type : application/pdf PDF Version : 1.3 Linearized : No Create Date : 2007:09:24 15:30:52 Page Count : 33EXIF Metadata provided by EXIF.tools