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LT1005CK-5 Linear Technology IC VREG 5 V FIXED POSITIVE LDO REGULATOR, 2 V DROPOUT, MBFM2, TO-3, 4 PIN, Fixed Positive Single Output LDO Regulator
LT1005CT-5 Linear Technology IC VREG 5 V FIXED POSITIVE REGULATOR, PSFM, Fixed Positive Single Output Standard Regulator
LT5537EDDB#TR Linear Technology LT5537 - Wide Dynamic Range RF/IF Log Detector; Package: DFN; Pins: 8; Temperature Range: -40°C to 85°C
LT5537EDDB#TRM Linear Technology LT5537 - Wide Dynamic Range RF/IF Log Detector; Package: DFN; Pins: 8; Temperature Range: -40°C to 85°C
LT5537EDDB#TRPBF Linear Technology LT5537 - Wide Dynamic Range RF/IF Log Detector; Package: DFN; Pins: 8; Temperature Range: -40°C to 85°C
LT5537EDDB#PBF Linear Technology LT5537 - Wide Dynamic Range RF/IF Log Detector; Package: DFN; Pins: 8; Temperature Range: -40°C to 85°C

LOG RX2 1005 Datasheets Context Search

Catalog Datasheet MFG & Type PDF Document Tags
1999 - LOG RX2

Abstract: log tx2 MT8840 MH88632 MH88631 MH88524 MH88510 MH88500 tx2/rx2 MT8816
Text: Circuit 1 RX2 Receive Gain Circuit 2 TX2 2-4 Wire Circuit 1 JUN1 Transmit Gain , MH88524 Preliminary Information RX1 JUN1 TX1 VDD AGND VEE IC TX2 JUN2 RX2 1 2 3 4 5 , referenced transmit and receive speech path. 10 RX2 Receive 2 (Input). 4-Wire ground (AGND , 2-4 Wire circuits are tested. TX, RX and Junctor actually refer to TX1, RX1 and JUN1; and TX2, RX2 and , resistance are 75W + 75, this configuration gives optimum return loss. Transhybrid Loss THL = log (VRX


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88631 LOG RX2 log tx2 MT8840 MH88632 MH88524 MH88510 MH88500 tx2/rx2 MT8816
Not Available

Abstract: No abstract text available
Text: 9161-002-158-NA Features i - RX1 JUN1 TX1 VDD AGND VEE IC ■nu JUN2 RX2 -"— 1 â , Circuit 1 TX1 I - RX2 I - TX2 -I 2-4 Wire Circuits - ÍJ U N 2 JUN1 Transmit , Input 1.0V Crosstalk, Circuit 2 tol JUN2 to JUN1 JUN2 toTX1 RX2toJUN1 RX2 to TX1 80 80 80 80 dB dB dB dB 200-3400 Hz JUN2 to JUN1 JUN2 toTX1 RX2to JUN1 RX2 to TX1 60 60 60 , and Junctor actually refer to TX1, RX1 and JUN1; and TX2, RX2 and JUN2. All of the above test


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88524 MH88631 15kHz. MT8840,
2001 - LOG RX2

Abstract: log tx2 IC tx2 MH88500 MH88510 MT8816 MH88631 MH88632 MT8814 MT8840
Text: Circuit 1 April 1995 RX2 Receive Gain Circuit 2 TX2 2-4 Wire Circuit 1 JUN1 , Diagram 1 MH88524 Preliminary Information RX1 JUN1 TX1 VDD AGND VEE IC TX2 JUN2 RX2 , Ground referenced transmit and receive speech path. 10 RX2 Receive 2 (Input). 4-Wire ground , refer to TX1, RX1 and JUN1; and TX2, RX2 and JUN2. All of the above test conditions use 754 connected , configuration gives optimum return loss. Transhybrid Loss THL = log (VRX/VTX) Transhybrid loss is maximised


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88631 LOG RX2 log tx2 IC tx2 MH88500 MH88510 MT8816 MH88632 MT8814 MT8840
2002 - log tx2

Abstract: LOG RX2 MT8816 MT8840 MT8814 MH88632 MH88631 MH88524 MH88510 MH88500
Text: Circuit 1 April 1995 RX2 Receive Gain Circuit 2 TX2 2-4 Wire Circuit 1 JUN1 , Diagram 1 MH88524 Preliminary Information RX1 JUN1 TX1 VDD AGND VEE IC TX2 JUN2 RX2 , Ground referenced transmit and receive speech path. 10 RX2 Receive 2 (Input). 4-Wire ground , refer to TX1, RX1 and JUN1; and TX2, RX2 and JUN2. All of the above test conditions use 754 connected , configuration gives optimum return loss. Transhybrid Loss THL = log (VRX/VTX) Transhybrid loss is maximised


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88631 log tx2 LOG RX2 MT8816 MT8840 MT8814 MH88632 MH88524 MH88510 MH88500
2003 - LOG RX2

Abstract: MH88524 MT8816 MT8814 MH88632 MH88631 IC tx2 MH88510 MH88500 log tx2
Text: Circuit 1 April 1995 RX2 Receive Gain Circuit 2 TX2 2-4 Wire Circuit 1 JUN1 , Diagram 1 MH88524 Preliminary Information RX1 JUN1 TX1 VDD AGND VEE IC TX2 JUN2 RX2 , Ground referenced transmit and receive speech path. 10 RX2 Receive 2 (Input). 4-Wire ground , refer to TX1, RX1 and JUN1; and TX2, RX2 and JUN2. All of the above test conditions use 754 connected , configuration gives optimum return loss. Transhybrid Loss THL = log (VRX/VTX) Transhybrid loss is maximised


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88631 LOG RX2 MH88524 MT8816 MT8814 MH88632 IC tx2 MH88510 MH88500 log tx2
1995 - LOG RX2

Abstract: log tx2 IC tx2 2-wire intercom LOG RX1 tx2/rx2 hybrid 2-4 wire telephone hybrid 2wire to 4wire 2-4 Wire converter TX280
Text: reliability. Intercom RX1 Receive Gain Circuit1 TX1 Transmit Gain Circuit 1 RX2 TX2 , Information RX1 JUN1 TX1 VDD AGND VEE IC TX2 JUN2 RX2 1 2 3 4 5 6 7 8 9 10 Figure 2 , receive speech path. 10 RX2 Receive 2 (Input). 4-Wire ground (AGND) referenced audio output , and JUN1; and TX2, RX2 and JUN2. All of the above test conditions use 754 connected between Junctor , resistance are 75W + 75, this configuration gives optimum return loss. Transhybrid Loss THL = log (VRX


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 15kHz MT8840, LOG RX2 log tx2 IC tx2 2-wire intercom LOG RX1 tx2/rx2 hybrid 2-4 wire telephone hybrid 2wire to 4wire 2-4 Wire converter TX280
1996 - LOG RX2

Abstract: IC tx2 log tx2 LOG RX1 2-4 Wire converter MT8816 2-wire intercom 4-wire to 2-wire hybrid MH88631 MH88524
Text: Circuit 1 RX2 Receive Gain Circuit 2 TX2 2-4 Wire Circuit 1 JUN1 Transmit Gain , MH88524 Preliminary Information RX1 JUN1 TX1 VDD AGND VEE IC TX2 JUN2 RX2 1 2 3 4 5 , referenced transmit and receive speech path. 10 RX2 Receive 2 (Input). 4-Wire ground (AGND , 2-4 Wire circuits are tested. TX, RX and Junctor actually refer to TX1, RX1 and JUN1; and TX2, RX2 and , resistance are 75W + 75, this configuration gives optimum return loss. Transhybrid Loss THL = log (VRX


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88631 15kHz LOG RX2 IC tx2 log tx2 LOG RX1 2-4 Wire converter MT8816 2-wire intercom 4-wire to 2-wire hybrid MH88524
log rx2 1015

Abstract: LOG RX2 1005 Dialer mc14069ub motorola
Text: PIN ASSIGNMENT Vd d C 1 Rx1 [ - - £ r > 3 o- 16 ] v c c ] D01 Tx1 [ DO Rx2 C < 0 p - , . DRIVERS Rx1, Rx2 , Rx3 Receive Data Input (Pins 2, 4, 6) These are the EIA 232-E receive signal inputs , transfer requires level shifting between the TTL/CMOS log ic levels of the computer or modem and the high , -25 CONNECTOR 10k£2 RxA1 SQT RING 12 DI2 NC 13 D02 10 Tx2 o - ö -| 10ki2 r-^ A / - Rx2 , OUT6 OUT5 IN6 IN5 12 10 13 11 MC145406 Tx RTS CD CTS Rx SG V SS ' VSS Rx1 Rx2 Rx3 Tx1 Tx2 Tx3 4


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PDF MC145406/D 232-E -232-D MC145406 300-i2 MC145406 log rx2 1015 LOG RX2 1005 Dialer mc14069ub motorola
Not Available

Abstract: No abstract text available
Text: 15 RX2 + -o INSERTION LOSS -1 .2 dB MAX 1 - 4 0 MHz RETURN LOSS, 1000BT (Z OUT = 100 , 2 2 *L 0 G 10( f/1 0 ) dB MIN 2 MHz -5 0 MHz -10+20* LOG io (f/8 0 MHz) dB M IN dB MIN , RATING 13 RX2 - 4 0 -1 0 0 3 5 0 uH MIN -5 0 MHz —0 .2 —0 .0 0 2 * f~ 1-4 dB MAX


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PDF H2053BFNL
Not Available

Abstract: No abstract text available
Text: '- ' i— * _ ■— ■— '-_ IC e TX2 ■= JUN2 LU RX2 1— c , Voltage. Typically +5V. 5 AGND 6 VEE 7 IC 8 TX2 9 JUN2 10 RX2 , actually refer to TX1, RX1 and JUN1; andTX2, RX2 and JUN2. All of the above test conditions use 754Î2 , = log (VRX/VTX) Transhybrid loss is maximised when the JUNi termination impedance is 754W. In , RX2 TX2 VDD AGND V EE 5 V Ò +5V -5V Figure 7 - MH88524 Application Circuit


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88631 MT8814
2008 - LOG RX2

Abstract: M3601 A2S22 B-2607 A1S21 A1S11 s44 sma M34 -2L log tx2 83167
Text: b2 RX1 TX1 TX2 RX2 RX3 CMOS Control/Driver and ESD V1 V2 RX4 a1 & a2 , ANT (Antenna) TX1 TX2 RX1 RX2 6 RX3 7 7 Port b1 Port 1 2 3 4 5 RX4 , P1 VNA Select the remaining switch states in turn: ANT to TX2, RX1, RX2 , RX3, and RX4; and , S41, S14, S44 RX2 S51, S15, S55 RX3 S61, S16, S66 RX4 S71, S17, S77 TX2 S32, S23 RX1 S42, S24 RX2 S52, S25 RX3 S62, S26 RX4 S72, S27 RX1 S43, S34


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2013 - t 2a/radar amplifier s-band

Abstract: No abstract text available
Text: -90° 11 GND 31 +5V_ RX2 RX1-phase 6 Ref Phase -180° 12 RF_RX1 32 GND , SPDT-B 34 GND RX2-atten 1 Ref Loss 1 dB 15 -5V_ LOG 35 -5V_AMP RX1-atten 2 Ref Loss 2 dB 16 +5V_ LOG 36 GND RX2-atten 2 Ref Loss 2 dB 17 SPDT-A , ) Gain (dB) 28 22 19 25 22 19 H - RX2 16 2.7 2.9 3.1 3.3 16 3.5 , 19 25 22 19 V - RX2 16 16 2.7 2.9 3.1 3.3 3.5 2.7 2.9 Frequency


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PDF MAIA-009579 MAIA-009579 pat78 40-Lead S2083 t 2a/radar amplifier s-band
mc145406

Abstract: LOG RX2 1005 log rx2 1015
Text: power supply ground. DRIVERS Rx1, Rx2 , Rx3 Receive Data Input (Pins 2, 4, 6) These are the EIA 232 , . Electrically this transfer requires level shifting between the TTL/CMOS log ic levels of the computer or modem , ~ Tx2 3 EIA 232-E DB-25 CONNECTOR NC 13 D02 lO k ii Rx2 RING Exl 10k FB Va g CDT 0.1 nF , 10.05 0.75 0.25 INCHES MIN MAX 0.411 0.400 0.299 0.292 0.104 0.093 0.014 0.019 0.035 0.020 0.050 BSC


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PDF MC145406/D 232-E S-232-D MC145406 MC145406 LOG RX2 1005 log rx2 1015
Not Available

Abstract: No abstract text available
Text: - MAX14972 TX2+ TX+ RX2 + SINGLE DIFFERENTIAL PAIR TX2- GND USB 3.0 DEVICE 100nF (X7R) 100nF (X7R) RX- RX+ 100nF (X7R) 100nF (X7R) RX+ MIDPLANE TX1+ 100nF (X7R) TX- RX2 , . VTX-DIFF-NTB-PP VTX-DIFF-TB-PP DE(dB) = 20 log VTX-DIFF-NTB-PP VTX-DIFF-TB-PP Figure 1. Illustration of , VIEW EQ2 Pin Configuration 18 17 16 15 14 13 RX2 + 19 12 TX2+ RX2 , Three-State Input Equalization Control, Channel 2. Leave EQ2 unconnected for default state. 19 RX2


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PDF MAX14972 MAX14972 24-pin
2008 - gsm modem pic interface block diagram

Abstract: sms sending code for pic to gsm modem interfacing PIC Microcontroller interfacing GSM Modem SIM300 RJLD-043TC PIC18F97J60 pic rs232 to gprs pic to gsm modem interfacing code for sms sending using pic sim300d_hd_v2
Text: 92 91 90 89 88 87 84 83 C34 RJLD-043TC 3V TX2 RX2 SCL SDA SDI1 SDO 1 SCK1 SS1 UEXT-1 UEXT , STATUS PWRKEY US B _P RE S E NT 1K RG0/ECCP3/P3A RG1/TX2/CK2 RG2/ RX2 /DT2 RG3/CCP4/P3D RG4/CCP5/P1D RG5 RG6 RG7 71 70 52 51 14 11 10 38 TX2 RX2 IN1 IN2 LED RELAY2 RELAY1 4 SDA VDD SCL ALERT , for your custom application. UEXT: Pin # 1 2 3 4 5 6 7 8 9 10 Signal Name VCC GND TX2 RX2 SCL SDA , OPT_TEMP connector, reflect with log . 0 of PIC18F97J60 input. Optocouple 2 ­ OPT2 (H11A817SMD) - 5V-12V


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PDF PIC18F97J60 900/1800/1900Mhz 909-PIC-GSM gsm modem pic interface block diagram sms sending code for pic to gsm modem interfacing PIC Microcontroller interfacing GSM Modem SIM300 RJLD-043TC pic rs232 to gprs pic to gsm modem interfacing code for sms sending using pic sim300d_hd_v2
2012 - Not Available

Abstract: No abstract text available
Text: ) TX+ RX2 + SINGLE DIFFERENTIAL PAIR 100nF (X7R) RX- RX+ 100nF (X7R) 100nF (X7R) RX+ MIDPLANE TX1+ 100nF (X7R) TX- 2.2µF TX2- GND USB 3.0 DEVICE 100nF (X7R) TX- RX2 , % and 80% levels. VTX-DIFF-NTB-PP VTX-DIFF-TB-PP DE(dB) = 20 log VTX-DIFF-NTB-PP , CM VCC TOP VIEW EQ2 Pin Configuration 18 17 16 15 14 13 RX2 + 19 12 TX2+ RX2 - 20 11 TX2- 10 GND 9 RX1+ 8 RX1- 7 N.C. GND 21


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PDF MAX14975 MAX14975 24-pin
2008 - free circuit diagram of USB modem using gsm sim

Abstract: PIC Microcontroller interfacing GSM Modem gsm mplab c18 RAS-1215 pic rs232 to gprs PIC Microcontroller GSM Modem schematic GSM Modem USB gsm modem pic interface block diagram SIM300D_HD_V2 sms sending code for pic to gsm modem interfacing
Text: /P1B(2) RG0/ECCP3/P3A RG1/TX2/CK2 RG2/ RX2 /DT2 RG3/CCP4/P3D RG4/CCP5/P1D RG5 RG6 RG7 RF0 , NT STATUS PWRKEY TX2 RX2 IN1 IN2 LED RELAY2 RELAY1 SS1 RTS CTS DTR DCD RI , LED3 O PT2 red 1 BZV55C5V1(mini-melf) Z2 SCL,SDA 3V TX2 RX2 SCL SDA SDI1 SDO 1 SCK1 , RX2 5 SCL 6 SDA 7 SDI1 8 SDO1 9 SCK1 10 SS1 UEXT is connector , terminal and negative voltage or GND of '-' terminal of OPT_TEMP connector, reflect with log . 0 of


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PDF PIC18F97J60 900/1800/1900Mhz free circuit diagram of USB modem using gsm sim PIC Microcontroller interfacing GSM Modem gsm mplab c18 RAS-1215 pic rs232 to gprs PIC Microcontroller GSM Modem schematic GSM Modem USB gsm modem pic interface block diagram SIM300D_HD_V2 sms sending code for pic to gsm modem interfacing
LOG RX2

Abstract: RX-2D rx2d
Text: RXORXI R X O a ju Z8 MS Vcc V dd T X O att TXIati Vb P D tx DET1t*2 D ETO rx2 D E T O rx2 DETIrx2 Cr Vc , N T R O L BO X In figure 6, each signal coming into the log amplifier is amplified and then inputted , conditions: 1) R e c e iv e M o d e D E T O rx l < D E T O rxI , O ETO rx2 < DETO r*2, PDtx. X , P D r x : 1 2} T ran sm it M o d e D E T O rx l » D E T O rx I , D ETO rx2 » D E T O rx2 , P D , x : 1, PD r x , O rxI, < D E T O r x I. » D E T O rx I, D ETO rx2 DETOncZ D ETO raZ D E T O tx2 » D E T O bx2. < D E


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PDF KA8601C KA8601C KA860IC LOG RX2 RX-2D rx2d
2006 - LOG RX2

Abstract: IC tx2 MT8804 MT8816 log tx2 MH88510 MH88524 MH88632 MT8814 MT8840
Text: Circuit1 Transmit Gain Circuit 1 April 1995 RX2 Receive Gain Circuit 2 TX2 2-4 Wire , AGND VEE IC TX2 JUN2 RX2 1 2 3 4 5 6 7 8 9 10 Figure 2 - Pin Connections Pin , Junctor 2 (Transmit and Receive). Ground referenced transmit and receive speech path. 10 RX2 , are tested. TX, RX and Junctor actually refer to TX1, RX1 and JUN1; and TX2, RX2 and JUN2. All of the , resistance are 75W + 75 , this configuration gives optimum return loss. Transhybrid Loss THL = log (VRX


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 LOG RX2 IC tx2 MT8804 MT8816 log tx2 MH88510 MH88524 MH88632 MT8814 MT8840
2008 - Not Available

Abstract: No abstract text available
Text: /CK2 RG2/ RX2 /DT2 RG3/CCP4/P3D RG4/CCP5/P1D RG5 RG6 RG7 RH0/A16 RH1/A17 RH2/A18 RH3/A19 RH4 , -12 EXT2-13 EXT2-14 EXT2-15 71 70 52 51 14 11 10 38 TX2 RX2 IN1 IN2 LED RELAY2 RELAY1 , RX2 SCL SDA SDI1 SDO 1 SCK1 SS1 R56 EXT2-16 EXT2-17 EXT2-18 EXT2-19 EXT2-20 EXT2 , 2 GND 3 TX2 4 RX2 5 SCL 6 SDA 7 SDI1 8 SDO1 9 SCK1 , of OPT_TEMP connector, reflect with log . 0 of PIC18F97J60 input. Optocouple 2 – OPT2 (H11A817SMD


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PDF PIC18F97J60 900/1800/1900Mhz
2001 - LOG RX2

Abstract: 2-wire intercom INTERCOM FULL-duplex log tx2 tx2/rx2 rx1 tx1 IC tx2 MH88510 MH88524 MH88631
Text: Circuit 1 April 1995 RX2 Receive Gain Circuit 2 TX2 2-4 Wire Circuit 1 JUN1 , Diagram 1 MH88524 Preliminary Information RX1 JUN1 TX1 VDD AGND VEE IC TX2 JUN2 RX2 , Ground referenced transmit and receive speech path. 10 RX2 Receive 2 (Input). 4-Wire ground , refer to TX1, RX1 and JUN1; and TX2, RX2 and JUN2. All of the above test conditions use 754 connected , configuration gives optimum return loss. Transhybrid Loss THL = log (VRX/VTX) Transhybrid loss is maximised


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88631 LOG RX2 2-wire intercom INTERCOM FULL-duplex log tx2 tx2/rx2 rx1 tx1 IC tx2 MH88510 MH88524
2001 - Not Available

Abstract: No abstract text available
Text: Circuit1 Transmit Gain Circuit 1 April 1995 RX2 Receive Gain Circuit 2 TX2 2-4 Wire , VEE IC TX2 JUN2 RX2 1 2 3 4 5 6 7 8 9 10 Figure 2 - Pin Connections Pin , Junctor 2 (Transmit and Receive). Ground referenced transmit and receive speech path. 10 RX2 , are tested. TX, RX and Junctor actually refer to TX1, RX1 and JUN1; and TX2, RX2 and JUN2. All of the , return loss. Transhybrid Loss THL = log (VRX/VTX) Transhybrid loss is maximised when the JUNi


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840
Not Available

Abstract: No abstract text available
Text: 8 9 TX1 VDD AGND VEE IC TX2 JUN2 10 RX2 Receive 1 (Input). 4-Wire ground (AGND , . 0DCH4Û5 SO? MH88524 Transhybrid Loss Application with MT8840, MH88500 and MH88524 THL = 20 log , Junctor actually refer to TX1, RX1 and JUN1; and TX2, RX2 and JUN2. A ll of the above test conditions use , TX1 JUN2 RX2 n TX2 VOUT V DD A G N D V EE ITT . ru V .t el CT (C , and VOUT JUN2. Apply VIN RX2 and measure VOUT TX1 and VOUT JU N 1. Apply VIN JUN2 and measure VOUT


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PDF MH88524 50kHz) MH88630/631, MH88632, MH88500 MT8840 MH88524 10-Pin MH88631
RX- 2 -G

Abstract: No abstract text available
Text: determined by 100KQ and 47pF. 4. ATTENUATOR CONTROL BOX In figure6, each signal coming in to the log , rX1, D E T O tx2 < D E T O rx2 , PDtx , X, PD RX: 1 2) Transmit Mode D E T O txI > D E T O rX1, D ETO tx2 > D E T O rX2 , PD tx: 1, PD rx: X 3) Slow Idle Mode D E T O txI > D E T O rx1, D ETO tx2 > D E T O rx2 , PD tx: 0, PD rx: X D E TO tx I < D E T O rx1, D E TO tx2 < D E T O rx2 , PD tx: 0, PD bx: X D E T O tx1 < D E T O rx1, D ETO tx2 > D E T O rx2 , PDtx: 0, PD hx: X D E TO tx I > D E T O


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PDF KA8601 KA8601 KSC709Y KSC945Y 10Kohm 10uF/50V 220pF 2uF/10V RX- 2 -G
Not Available

Abstract: No abstract text available
Text: o 20 + RX2 + R D 4 11 -o 14 +RX4 —RD2 6 o 19 —RX2 —RD4 12 o 13 — RX4 , MIN 2 MHz 3 0 -1 0 0 MHz DIFFERENTIAL TO COMMON MODE REJECTION - 5 0 dB MIN -43+22* LOG ,o(f/3 0


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PDF J-STD-003A LOG10 LOG10 X1294FN
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