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Part Manufacturer Description PDF & SAMPLES
CP2500DC54PEZ GE Critical Power CP2500DC54PE Compact Power Line DC/DC Converter, Input: -40 to -72Vdc; Outputs: ±54 Vdc @ 2500W; 5 Vdc @ 4W
PIM400Z GE Critical Power PIM400 Series; ATCA Board Power Input Module, -36 to -75 Vdc; 400W/10A
APXH006A0X4-SRZ GE Critical Power PicoTLynx™ 6A: Non-Isolated DC-DC Power Module, 2.4Vdc –5.5Vdc input; 0.6Vdc to 3.63Vdc output; 6A Output Current
APTH020A0X3-SR GE Critical Power TLynxTM: Non-Isolated DC-DC Power Module: 2.4Vdc –5.5Vdc input; 0.6Vdc to 3.63Vdc output; 20A Output Current
APXS006A0X4-SRZ GE Critical Power 12V PicoTLynxTM 6A: Non-Isolated DC-DC Power Module, 4.5Vdc –14Vdc input; 0.59Vdc to 5.5Vdc output; 6A Output Current
APTS020A0X3-SRDZ GE Critical Power 12V TLynxTM 20A: Non-Isolated DC-DC Power Module, 4.5Vdc –14Vdc input; 0.69Vdc to 5.5Vdc output; 20A Output Current

"dc blocking capacitor"

Catalog Datasheet MFG & Type PDF Document Tags
Abstract: ) HSM_TX_P7 Output Differential transmit data output before DC blocking capacitor 2 HSM_RX_P7 Input Differential transmit data input before DC blocking capacitor 3 HSM_TX_N7 Output Differential transmit data output before DC blocking capacitor 4 HSM_RX_N7 Input Differential transmit data input before DC blocking capacitor 5 HSM_TX_P6 Output Differential transmit data output before DC blocking capacitor 6 HSM_RX_P6 Input Differential transmit data input TerasIC Technologies
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Abstract: capacitor at MSC8156 pin SRIO0_RXD0_N I DC blocking capacitor at MSC8156 pin SRIO0_RXD1_P I DC blocking capacitor at MSC8156 pin SRIO0_RXD1_N I DC blocking capacitor at MSC8156 pin SRIO0_RXD2_P I DC blocking capacitor at MSC8156 pin SRIO0_RXD2_N I DC blocking capacitor at MSC8156 pin SRIO0_RXD3_P I DC blocking capacitor at MSC8156 pin SRIO0_RXD3_N I DC blocking capacitor at MSC8156 pin SRIO0_REFCLK_P I DC blocking capacitor at MSC8156 pin Freescale Semiconductor
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DDR3 timing MT41J64M16BLA-15E MSC8156 datasheet S25FL128P MICRON ddr3 MT41J64M16 MT41J64M16 MSC8156MDDS
Abstract: the AGC amplifier, CDMA channel.Requires a DC blocking capacitor. A parallel differential DC coupled , - Inverting analog input of the AGC amplifier, CDMA channel. Requires a DC blocking capacitor. A parallel , analog input of the AGC amplifier, FM channel. Requires a DC blocking capacitor. A parallel differential , IF_FM- Inverting analog input of the AGC amplifier, FM channel. Requires a DC blocking capacitor. A , . Use a 50 power to current converter. See applications diagram. Requires a DC blocking capacitor. 15 Harris Semiconductor
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HFA3765 HFA3765IA HFA3765IA96 855292 SX043 SAWTEK 855292 250MH IS-95A 5M-1982
Abstract: AGC amplifier, CDMA channel .Requires a DC blocking capacitor. A parallel differential DC coupled , the AGC amplifier, CDMA channel. Requires a DC blocking capacitor. A parallel differential DC coupled , the AGC amplifier, FM channel. Requires a DC blocking capacitor. A parallel differential DC coupled , the AGC amplifier, FM channel. Requires a DC blocking capacitor. A parallel differential DC coupled , Oscillator. Use a 50 power to current converter. See applications diagram. Requires a DC blocking capacitor Harris Semiconductor
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ISO9000 1-800-4-HARRIS
Abstract: applications diagram. Requires a DC blocking capacitor. IF output amplifiers ground return. Negative I channel baseband output. Requires a DC blocking capacitor. Positive I channel baseband output. Requires a DC , DC blocking capacitor. Positive Q channel baseband output. Requires a DC blocking capacitor. IF , the quadrature demodulator. Requires a DC blocking capacitor. Negative input of the quadrature demodulator. Requires a DC blocking capacitor. AGC amplifier main ground return. Ground. Connect to a solid Intersil
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HFA376
Abstract: channel .Requires a DC blocking capacitor. A parallel differential DC coupled resistor setting the input , analog input of the AGC amplifier, FM channel. Requires a DC blocking capacitor. A parallel differential , power to current converter. See appli­ cations diagram. Requires a DC blocking capacitor. 15 GND_AMP 16 IOUT- Negative I channel baseband output. Requires a DC blocking capacitor. 17 IOUT+ Positive I channel baseband output. Requires a DC blocking capacitor. 18 GND 19 -
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Abstract: Balanced IF input for the buffer amplifier for the first gain stage. An external DC blocking capacitor of , to ground through the DC blocking capacitor. S ee pin 1. LO input for the mixer. An external DC blocking capacitor of 4.7nF is required. vp n > 1.5 kr LO O - () C 4 IF 1 O U T Single-ended output of the mixer. An external DC blocking capacitor of 4 .7 n F or a , performance. Balanced IF input for the second gain stage. An external DC blocking capacitor of 4 .7 n F is -
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RF2612 RF2401 2612PC8A
Abstract: Balanced IF input for the buffer amplifier for the first gain stage. An external DC blocking capacitor of , Balanced IF input for the buffer amplifier for the first gain stage. An external DC blocking capacitor of , the DC blocking capacitor. LO input for the mixer. An external DC blocking capacitor of 4.7 nF is , output of the mixer. An external DC blocking capacitor of 4.7nF or a DC blocking filter is needed. It is , input for the second gain stage. An external DC blocking capacitor of 4.7nF is recommended. Ó K Q -
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capacitor J400 800-J600 ir*7625 350MH
Abstract: stage. An external DC blocking capacitor of 4.7nF is recommended. 5 k IF15 k IF1+ Interface , the second gain stage. An external DC blocking capacitor of 4.7nF is recommended. 5 6 GND , . An See pin 1. external DC blocking capacitor of 4.7nF is recommended. When a single-ended input is used this port can be connected to ground through the DC blocking capacitor. Ground connection. Keep , gain is typically 38dB. An external DC blocking capacitor of 4.7nF or a DC blocking filter is needed RF Micro Devices
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RF2611
Abstract: + Non-inverting analog input of the AGC amplifier, CDMA channel.Requires a DC blocking capacitor. A parallel , IF_CDMA- Inverting analog input of the AGC amplifier, CDMA channel. Requires a DC blocking capacitor. A , + Non-inverting analog input of the AGC amplifier, FM channel. Requires a DC blocking capacitor. A parallel , IF_FM- Inverting analog input of the AGC amplifier, FM channel. Requires a DC blocking capacitor. A , . Use a 50 power to current converter. See applications diagram. Requires a DC blocking capacitor. 15 Intersil
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Abstract: connected to ground through the DC blocking capacitor. LO input for the mixer. An external DC blocking , GND 6 I F 2 IN + Single-ended output of the mixer. An external DC blocking capacitor of , for best performance. Balanced IF input for the second gain stage. An external DC blocking capacitor , input for the second gain stage. An external DC blocking capacitor of 4.7nF is recommended. When a single-ended input is used this port can be connected to ground through the DC blocking capacitor. An -
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Abstract: amplifier for the first gain stage. An external DC blocking capacitor of 4.7 nF is recommended. 2 DEC1 Balanced IF input for the buffer amplifier for the first gain stage. An external DC blocking capacitor of , the DC blocking capacitor. 3 LO LO input for the mixer. An external DC blocking capacitor of 4.7 nF is required. 4 IF1 OUT Single-ended output of the mixer. An external DC blocking capacitor of 4.7 nF , gain stage. An external DC blocking capacitor of 4.7 nF is recommended. 7 DEC2 Balanced IF input for -
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RF2602 j400 7341-D RF2602-1 TD04131 RF2602PCBA RF2602PCB
Abstract: buffer amplifier for the first gain stage. An external DC blocking capacitor of 4.7nF is recommended , through the DC blocking capacitor._ See pin 1. LO LO input for the mixer. An external DC blocking capacitor of 4.7nF is required. lo o- IF1 OUT Single-ended output of the mixer. An external DC blocking capacitor of 4.7nF or a DC blocking filter is needed. It is highly recommended to use an IF filter between , the second gain stage. An external DC blocking capacitor of 4.7nF is recommended. to oc UJ 0. s -
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digital gain control
Abstract: the buffer amplifier for the first gain stage. An external DC blocking capacitor o f 4.7 nF is , through the DC blocking capacitor. LO Input for the mixer. An external DC blocking capacitor o f 4.7 nF is required. Single-ended output o f the mixer. An external DC blocking capacitor o f 4.7 nF or a DC , blocking capacitor o f 4.7 nF is recommended. Balanced IF input for the second gain stage. An external DC , to ground through the DC blocking capacitor. An external decoupling capacitor of 4.7 nF is required -
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RF2602-3 RF2602-4
Abstract: - Balanced IF input for the buffer amplifier for the first gain stage. An external DC blocking capacitor of , the DC blocking capacitor. 3 GND Ground connection. Keep traces physically short and connect , typically 38dB. An external DC blocking capacitor of 4.7nF or a DC blocking filter is needed. It is highly , as pin 3. Balanced IF input for the second gain stage. An external DC blocking capacitor of 4.7nF , . An external DC blocking capacitor of 4.7nF is recommended. When a single-ended input is used this -
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Abstract: . An external DC blocking capacitor of 4.7 nF is recommended. 2 DEC1 Balanced IF input for the buffer amplifier for the first gain stage. An external DC blocking capacitor of 4.7 nF is recommended. When a single-ended input is used this port can be connected to ground through the DC blocking capacitor. 3 GND , (pin 17). When G32 is high the gain is typically 38 dB. An external DC blocking capacitor of 4.7 nF or , second gain stage. An external DC blocking capacitor of 4.7 nF is recommended. 7 DEC2 Balanced IF input -
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RF2601 9507 ic 4060 pin configuration diagram RF2601-3 T004131 0DD0242 00002M3
Abstract: stage. An external DC blocking capacitor of 4.7nF is recommended. Interface Schematic A 5k £ i , the buffer amplifier for the first gain stage. An See pin external DC blocking capacitor of 4.7nF is , (pin 17). When G32 is high the gain is typically 38dB. An external DC blocking capacitor of 4.7nF or a , external DC blocking capacitor of 4.7nF Is recommended. 1. V £ 1.2 kQ -W v - ) O IF 1 O U , through the DC blocking capacitor. An external decoupling capacitor of 4.7nF is required on this pin -
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x 300 f TQD4131
Abstract: . An external DC blocking capacitor of 4.7 nF is recommended. When a single-ended input is used this port can be connected to ground through the DC blocking capacitor. Ground connection. Keep traces , typically 38 dB. An external DC blocking capacitor o f4 .7 n F o r a D C blocking filter is needed. It is , . Same as pin 3. Balanced IF input for the second gain stage. An external DC blocking capacitor of 4.7 nF is recommended. Balanced IF input for the second gain stage. An external DC blocking capacitor of -
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RF2601-1 RF2601-4
Abstract: to 2GHz operation with 100pF external blocking capacitors in all RF paths DC Electrical , RF1 1 6 GND 2 5 RF2 3 4 V1 RFC V2 *External DC blocking capacitors , capacitors) Optimized performance can be achieved 100pF Optimized performance can be achieved >2.0GHz by decreasing blocking capacitor to , performance can be achieved 100pF Optimized performance can be TriQuint Semiconductor
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CSH210R 210R GRP1555C7H100JZ01 SC-70
Abstract: V1 GND RFC RF2 3 4 V2 *External DC blocking capacitors required; 100pF on pins 1 , increasing blocking capacitor to >100pF Optimized performance can be achieved >2.0GHz by decreasing blocking , can be achieved 100pF Optimized performance can be achieved >2.0GHz by decreasing blocking capacitor to , device exhibits excellent VSWRs and isolation and is useable from DC to 2.5 GHz. Applications: · · TriQuint Semiconductor
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