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Part Manufacturer Description Datasheet Download Buy Part
LT1025ACJ8 Linear Technology T.C. COLD JUNCTION COMPENSATOR
LT1012CJ8 Linear Technology IC COMPENSATED PREC OPAMP 8CDIP
LT1012DJ8 Linear Technology IC COMPENSATED PREC OPAMP 8-CDIP
LT1012IJ8 Linear Technology IC COMPENSATED PREC OPAMP 8-CDIP
LT1025CS8#PBF Linear Technology LT1025 - Micropower Thermocouple Cold Junction Compensator; Package: SO; Pins: 8; Temperature Range: 0°C to 70°C
LT1025CN8#PBF Linear Technology LT1025 - Micropower Thermocouple Cold Junction Compensator; Package: PDIP; Pins: 8; Temperature Range: 0°C to 70°C

electronic dispersion compensator Datasheets Context Search

Catalog Datasheet MFG & Type PDF Document Tags
2006 - BCM8105

Abstract: dispersion compensator BCM8128
Text: , electronic dispersion compensator (EDC), loss of signal (LOS) detection circuitry, and an advanced feature , BCM8105 ® MULTIRATE 10-GBPS CDR/DEMULTIPLEXER WITH ELECTRONIC DISPERSION COMPENSATION SUMMARY OF BENEFITS FEATURES · Fully integrated CDR and demultiplexer with AGC and electronic dispersion compensator · Extends the reach of single-channel and DWDM links · Improves optical link budget · Compensates 3000-ps/nm chromatic dispersion · Compensates 50 ps of digital group delay


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PDF BCM8105 10-GBPS 3000-ps/nm BCM8105 15-mm, 150-pin 8105-PB03-R dispersion compensator BCM8128
2004 - BCM8105

Abstract: electronic dispersion compensator demultiplexer BCM8128 150-Pin Dispersion Compensator
Text: ( electronic dispersion compensator ), LOS (loss of signal) detection circuitry and an advanced feature set , BCM8105 ® MULTI-RATE 10-GBPS CDR/DEMULTIPLEXER WITH ELECTRONIC DISPERSION COMPENSATION SUMMARY OF BENEFITS FEATURES · Fully integrated CDR and demultiplexer with AGC and Electronic Dispersion Compensator · Compensates 3000 ps/nm chromatic dispersion · Compensates 50 ps of digital group , Reduces need for expensive optics and passive dispersion BCM8105 OVERVIEW RB_LD TH_LOS0/1/2


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PDF BCM8105 10-GBPS BCM8105 150-pin 8105-PB02-R electronic dispersion compensator demultiplexer BCM8128 Dispersion Compensator
2006 - 10GBASE-LRM

Abstract: microcontroller pacemaker IQ2200 VSC8238 electronic dispersion compensator
Text: Gbps Advanced Electronic Equalization with Limiting Amplifier, and Clock and Data Recovery GENERAL DESCRIPTION: The VSC8238 device is a compact, fully integrated electronic dispersion compensator (EDC) and , TRANSPORT PHYSICAL LAYER VSC8238 10.3125 Gbps Advanced Electronic Equalization with Limiting Amplifier, and Clock and Data Recovery BLOCK DIAGRAM: Initialization and Control Link Monitor , DFE filter Provides superior modal dispersion compensation and exceeds 10GBASE-LRM specifications


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PDF VSC8238 10GBASE-LRM microcontroller pacemaker IQ2200 VSC8238 electronic dispersion compensator
DISPERSION COMPENSATING FIBER

Abstract: DISPERSION COMPENSATING FIBER SMF Dispersion Compensator Dispersion Compensation Module puregain Oclaro 40G 300 PS3200 dispersion compensating
Text: PowerShaper PS3200 PowerShaperTM PS3200 Tunable Dispersion Compensator Features: · Broad Dispersion Tuning Range · Flexible Substitute for Fixed DC · Software Configurable Optics · Compensates All DWDM Channels · Colorless - On or Off ITU Grid. · Broad Dispersion Pass-Band · Low Group Delay & Phase , 15 mm) The PowerShaperTM PS3200 tunable dispersion compensator (TDC) enables cost-effective and , are in millimeters. Complementary Products PowerShaperTM PS3300 tunable dispersion compensator


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PDF PS3200 RS232 PS3200 PS3300 PG1600P DISPERSION COMPENSATING FIBER DISPERSION COMPENSATING FIBER SMF Dispersion Compensator Dispersion Compensation Module puregain Oclaro 40G 300 dispersion compensating
DISPERSION COMPENSATING FIBER

Abstract: Dispersion Compensation Module SFM-110-02-S-D-A PS3300 Oclaro dispersion compensation fiber
Text: PowerShaper PS3300 PowerShaperTM PS3300 Tunable Dispersion Compensator , Small Form Factor , Pass-Band & Dispersion · RS232 or I^2C Command Interface · Set & Forget or Closed loop · Small Form Factor for Line Card Integration (90 x 70 x 12 mm) The PowerShaperTM PS3300 tunable dispersion compensator , design. Oclaro can customize the optical design of the PowerShaperTM Tunable Dispersion Compensator , Configurable Optics · Compensates All DWDM Channels · Colorless - On or Off ITU Grid. · Broad Dispersion


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PDF PS3300 RS232 PS3300 E2000, PG1600P DISPERSION COMPENSATING FIBER Dispersion Compensation Module SFM-110-02-S-D-A Oclaro dispersion compensation fiber
2002 - Dispersion Compensator

Abstract: Optical circulator TeraXion
Text: TH-TDC TUNABLE DISPERSION COMPENSATOR (PRELIMINARY) YOUR KEY ENABLER FOR INCREASED DATA RATES TeraXion's TH-TDC is a grating-based tunable dispersion compensator that meets the stringent needs of high , dispersion levels, very low group delay ripples, and low power consumption-all essential for emerging 40 Gb/s systems. The dispersion level provided by the component can be adjusted dynamically to counteract chromatic dispersion fluctuations resulting from climatic variations and component aging.These features


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PDF 658-TERA TERA032002 Dispersion Compensator Optical circulator TeraXion
Gennum APD

Abstract: laser fibre optic LED laser fibre optic semiconductor fibre optic multi mode graded index plastic fiber Sharp Semiconductor Lasers GO2922 GO2920 424M electronic dispersion compensator
Text: by a ' dispersion compensator '. This works by using a specially prepared length of fibre that has the , .6 Dispersion , .7 Inter Symbol Interference ( Dispersion ) Limited Links , refractive index at different wavelengths. In order to minimise spectral dispersion in the fibre, the source , spaced peaks. This limits their link length, due to chromatic dispersion , but it has the advantage that


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PDF 297M-2006 Gennum APD laser fibre optic LED laser fibre optic semiconductor fibre optic multi mode graded index plastic fiber Sharp Semiconductor Lasers GO2922 GO2920 424M electronic dispersion compensator
2009 - Not Available

Abstract: No abstract text available
Text: for external components includingstatic and transitional characteristics as well as dispersion of the , . Power save mode is active when output is set under 0.2V. Pin6 is a sag compensator input. VCC 8 , document are intended to be used with general-use electronic equipment or devices (such as audio visual equipment, office-automation equipment, communication devices, electronic appliances and amusement devices).


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PDF BA7664AFV 09065EAT02 BA7664AFV R0039A
2008 - Not Available

Abstract: No abstract text available
Text: characteristics as well as dispersion of the IC. Fig.1 2/4 Equivalent circuit Pin.No Pin name IN OUT , output terminal. Power save mode is active when output is set under 0.2V. Pin6 is a sag compensator input , document are designed to be used with ordinary electronic equipment or devices (such as audio visual equipment, office-automation equipment, communications devices, electrical appliances and electronic toys).


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PDF BA7664AFV BA7664AFV
2008 - BA7664AFV

Abstract: No abstract text available
Text: includingstatic and transitional characteristics as well as dispersion of the IC. Fig.1 2/4 Equivalent , . Pin6 is a sag compensator input. Pin6 6 7 MIXOUT2 MIXOUT1 0.9V 0.95V Pin7 8 , ordinary electronic equipment or devices (such as audio visual equipment, office-automation equipment, communications devices, electrical appliances and electronic toys). Should you intend to use these products


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PDF BA7664AFV BA7664AFV
2006 - Not Available

Abstract: No abstract text available
Text: p-Q Electronic Module PQDXXA , Catalogue HY30-3243/UK Introduction Pump with Standard Pressure Compensator , code F*S Pump with Load-Sensing Compensator , code FFC Ø0,8 Q PM P1 L L P PF A A P1 PM P1 L L , compensator operation. Lowest compensating pressure 12-15 bar • 9 piston and precompression technology , for lowest noise level • Complete compensator program • Thru drive for 100% nominal torque


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PDF HY30-3243/UK
2002 - Not Available

Abstract: No abstract text available
Text: one of two ways. If the temperature fluctuates, then an automatic compensator should be used. If the temperature is constant within several degrees C, then a manual compensator can be used. If no compensator is needed, a fixed resistor can be installed across the temperature compensator terminals , a function of the pH meter’s electronic circuit. As such, information and parts should be , compensator also should be in the buffer. In a similar way, a manual temperature compensator should be


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PDF unit/10Â
2007 - SCR based induction furnace circuit diagram

Abstract: thyristor control arc welding rectifier circuit SCR induction furnace circuit diagram buck converter with dsPIC thyristor control arc welding machines circuit TKK transformer induction furnace inverter firing board buck pfc diode KIV 66 AN1106
Text: of power electronic peripherals such as an Analog-to-Digital Converter (ADC) and a Pulse Width , Electronic Equipment (rectifiers, UPS systems, variable frequency drives, state converters, thyristor , to: · Erroneous operation of control system components · Damage to sensitive electronic equipment , electronic equipment V V (t) I I (t) t To reduce these problems of current harmonics, the , computing the product of the rectified input voltage, the voltage error compensator output and the voltage


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PDF AN1106 a536-4803 C01106A-page SCR based induction furnace circuit diagram thyristor control arc welding rectifier circuit SCR induction furnace circuit diagram buck converter with dsPIC thyristor control arc welding machines circuit TKK transformer induction furnace inverter firing board buck pfc diode KIV 66 AN1106
2006 - AN6052

Abstract: ERT-J1V FAN5032 FAN5031 FAN5019 mathcad INDUCTOR DESIGN ERTJ1V FAN5033 FAN50FC3 VR11
Text: ( i, Ro) := angle Re F4 s j 2 , Ro , Im F4 s j 2 , Ro Voltage Compensator Gain Fv(s) For most of applications using electrolytic-type dominant output capacitors, a 2-pole-1-zero compensator , placeholder for a 3-pole-2zero compensator is always recommended in the PCB layout to have flexibility to fine , -pole-2-zero compensator is usually mandatory. In this design example, electrolytic-type dominant output capacitors are used. The compensator design adopts an interactive approach. In such a condition, the control design


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PDF AN-6052 FAN5019, FAN5031, FAN5032, FAN5032B, FAN5033, FAN50FC3 AN6052 ERT-J1V FAN5032 FAN5031 FAN5019 mathcad INDUCTOR DESIGN ERTJ1V FAN5033 FAN50FC3 VR11
2009 - Analyzing, Measuring, and Stabilizing Feedback Control Loops in Switching Regulators and Converters

Abstract: Stabilizing Feedback Control Loops Lloyd H. Dixon Stabilizing Feedback Control Loops venable unitrode SEM-1100 dean venable Measuring and Stabilizing Feedback Control Loops in Switching Regulators and Converters, PowerCon7 SEM-1100 AN2016 AN2013
Text: / compensator . For this feedback loop to be stable, negative feedback is used. This means that the output , except that of the compensator . GFIX = GPWM GPS Eq. [8] If gCOMP represents the gain of the compensator , the open-loop transfer function of the simplified buck converter is then 2 Application , Response To provide the highest possible gain at low frequencies, the compensator is generally chosen to be an integrator. This means that the compensator has a pole at the origin (DC), a -1 gain slope


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2015 - Not Available

Abstract: No abstract text available
Text: electronic systems. From smart handhelds to data servers and wireless base stations, digital power , , system designers can develop more compact electronic products with small form factors or add more , compensator (ASCR) (Figure 2). With the ASCR compensator , the control loop will react to a voltage deviation , compensator block diagram shown in Figure 2 has two parallel paths for processing the quantized error voltage , € In this unique compensator structure, the duty cycle command is fed back to determine the effect of


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2010 - Not Available

Abstract: No abstract text available
Text: 870 AVE:9.655nA 910 AVE:921.7mV 900 860 AVE:870.1mV 850 VF DISPERSION MAP VF DISPERSION MAP IR DISPERSION MAP 100 90 REVERSE CURRENT:IR(nA) 80 70 60 50 40 30 20 10 0 IR DISPERSION , 2 1 0 Ct DISPERSION MAP AVE:1.17pF D1,D2 Ta=25 C VR=6V f=1MHz n=10pcs 10 9 CAPACITANCE BETWEEN TERMINALS:Ct(pF) 8 7 6 5 4 3 2 1 0 Ct DISPERSION MAP AVE:1.98pF D3,D4 VR=6V f=1MHz www.rohm.com ©2010 , RESERVE RECOVERY TIME:trr(ns) 9 8 7 6 5 4 AVE:1.93ns 3 2 1 0 trr DISPERSION MAP AVE:2.40ns D1,D2 D1 D3,D4


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PDF UMR11N OT-363 SC-88 R1010A
2005 - UMR12N

Abstract: 364pF
Text: =100mA n=30pcs D2 1040 1030 1020 AVE:1035.0mV VF DISPERSION MAP 9 REVERSE CURRENT:IR(nA) 0.7 4 1050 VF DISPERSION MAP 10 0.8 3 REVERSE VOLTAGE:VR(V) VR-Ct , CURRENT:IR(nA) 100 IR DISPERSION MAP 0 IR DISPERSION MAP Ct DISPERSION MAP Rev.A 2/3 , DISPERSION MAP Ct DISPERSION MAP ELECTROSTATIC DISCHARGE TEST ESD(KV) VR=6V 0 0 0 , =200pF R=0 C=100pF R=1.5k ESD DISPERSION MAP D2 AVE:13.56kV AVE:1.87kV C=200pF R=0 C


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PDF UMR12N OT-363 SC-88 UMR12N 364pF
2005 - tic 1060

Abstract: 400 kv ct DA228K
Text: 1050 1040 1030 1020 AVE:1035.0mV 1010 VF DISPERSION MAP 9 REVERSE CURRENT:IR(nA) 0.8 f=1MHz Ct13 VF DISPERSION MAP 10 Ta=25 VR=15V n=30pcs 80 10 1 D1 70 , REVERSE CURRENT:IR(nA) 100 IR DISPERSION MAP 0 IR DISPERSION MAP Ct DISPERSION MAP Rev.A , 10 1000 10 PEAK SURGE FORWARD CURRENT:IFSM(A) 20 Ct DISPERSION MAP Ct DISPERSION , RECOVERY TIME:trr(ns) 5 1000 C=200pF R=0 C=100pF R=1.5k ESD DISPERSION MAP D2 AVE


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PDF DA228K S0T-346 SC-59 05MIN tic 1060 400 kv ct DA228K
2005 - tic 1060

Abstract: DA228U
Text: 1020 AVE:1035.0mV 1010 VF DISPERSION MAP 9 REVERSE CURRENT:IR(nA) 0.8 f=1MHz 1 VF DISPERSION MAP 10 Ta=25 VR=15V n=30pcs 80 10 1 D1 70 1060 Ta=25 IF , (mA) 100 D2 D1 REVERSE CURRENT:IR(nA) 100 IR DISPERSION MAP 0 IR DISPERSION MAP Ct DISPERSION MAP Rev.A 2/3 DA228U Diodes 5 4 AVE:3.64pF 3 40 2 1 4 3 2 AVE:1.86pF 1 D2 30 20 10 D1 0 Ct DISPERSION MAP Ct DISPERSION MAP 1 D1


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PDF DA228U OT-323 SC-70 tic 1060 DA228U
2014 - 359C-Series

Abstract: No abstract text available
Text: 359C Series 1550 nm Dispersion Compensation Module DATASHEET | NOVEMBER 2014 MICROWAVE The 359C Series Dispersion Compensation Module provides a solution for dealing with existing high dispersion legacy installations. By providing a negative dispersion , fiber with high positive dispersion can be fully compensated. Typical dispersion compensation modules can increase the total fiber length by as much as 65%, while these highly efficient high dispersion fibers only increase the total fiber


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PDF E2000/APC 359C-Series
2007 - DA221M

Abstract: No abstract text available
Text: 5 D1 6 5 4 3 AVE:1.85pF 2 1 0 Ta=25 VR=15V n=30pcs D1 IR DISPERSION MAP Ta=25 VR=6V f=1MHz n=10pcs 7 1 0 IR DISPERSION MAP 0.8 0 RESERVE RECOVERY TIME , 10 9 10 0.9 VF DISPERSION MAP Ta=25 VR=15V n=30pcs 6 5 REVERSE VOLTAGE:VR(V , DISPERSION MAP 7 1 15 820 D2 D2 REVERSE VOLTAGE:VR(V) VR-Ct CHARACTERISTICS AVE , =100 Irr=0.1*IR n=10pcs D1 4 3 2 1 AVE:1.20ns 0 Ct DISPERSION MAP trr DISPERSION MAP


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PDF DA221M DA221M
2009 - RN242CS

Abstract: 8312MV
Text: CHARACTERISTICS 1 10 10 100 1000 FREQUENCY(MHz) Ct-f CHARACTERISTICS VF DISPERSION MAP 2 , TERMINALS:Ct(pF) 0.5 Ta=25°C f=1MHz VR=1V n=10pcs 0.4 0.3 0.2 Ct DISPERSION MAP , FORWARD CURRENT:IF(mA) rf DISPERSION MAP 5 ELECTROSTATIC DDISCHARGE TEST ESD(KV) Ta=25°C f=100MHz IF=10mA n=10pcs 1.4 1.6 1 0 1.5 1.7 1.1 AVE:0.256pF IR DISPERSION MAP , AVE:0.975 0.5 0 FORWARD CURRENT:IF(mA) rf DISPERSION MAP www.rohm.com ©2009 ROHM Co., Ltd


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PDF RN242CS R0039A RN242CS 8312MV
2005 - DAP236U

Abstract: No abstract text available
Text: 0.02 0.01 810 0.1 1 FORWARD CURRENT:IF(mA) rf-IF CHARACTERISTICS VF DISPERSION MAP 1 , 1 AVE:1.20ns 1 0.7 trr DISPERSION MAP 0.6 0.5 0.4 0.3 0.2 AVE:0.602 0 100 , DISRESION MAP Ct DISPERSION MAP 0.9 Ta=25 VR=6V IF=10mA RL=100 Irr=0.1*IR n=10pcs 4 0 , ) 0.8 0.1 IR DISPERSION MAP 20 0.9 0.6 0 10 Ifsm 8 PEAK SURGE FORWARD , CURRENT:IF(mA) rf DISPERSION MAP Ifsm 10 NUMBER OF CYCLES IFSM-CYCLE CHARACTERISTICS 100


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PDF DAP236U OT-323 SC-70 DAP236U
2005 - Not Available

Abstract: No abstract text available
Text: CHARACTERISTICS 1000 810 VF DISPERSION MAP 1 0.9 Ta=25 VR=30V n=30pcs 1 0.9 Ta=25 f=1MHz VR=1V n , ) 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 IR DISPERSION MAP AVE:0.0865nA 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 Ct DISPERSION MAP AVE:0.326pF FORWARD OPERATING RESISTANCE:rf() 0.8 0.8 2.3 2.2 2.1 2 1.9 1.8 1.7 1.6 1.5 AVE:2.199 FORWARD CURRENT:IF(mA) rf DISPERSION MAP 1 0.9 0.8 Ta=25 f=100MHz IF=10mA n , FORWARD CURRENT:IF(mA) rf DISPERSION MAP ESD DISPERSION MAP 2/2 Appendix Notes No technical


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PDF RN152G
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