PART |
Description |
Maker |
13LED20M-ST |
Typical optical and electrical characteristics.
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Anadigics Inc
|
AN649 |
HFTA-04.0: Optical/Electrical Conversion in SDH/SONET Fiber Optic Systems
|
Maxim Integrated Products, Inc. MAXIM[Maxim Integrated Products]
|
TX1.25GBIT/S |
Parallel Optical Links (PAROLI) - PAROLI?2 Tx AC, 1.25 Gbit/s, multistandard electrical interface
|
Infineon
|
Q62702-G0042 BGA312 |
Silicon Bipolar MMIC-Amplifier (Cascadable 50 W-gain block 11 dB typical gain at 1.0 GHz 9 dBm typical P-1dB at 1.0 GHz) From old datasheet system
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SIEMENS AG SIEMENS[Siemens Semiconductor Group]
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KT837L15 KT837W15 KT837L55 KT837L51 KT837W51 KT837 |
Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter C lead spacing .220 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter C lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter C lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter C lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter C lead spacing .320 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter A lead spacing .220 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter A lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter B lead spacing .320 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter B lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter B lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter A lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter B lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter C lead spacing .220 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells . Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter B lead spacing .320 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter A lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter B lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter B lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter C lead spacing .320 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter C lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter C lead spacing .320 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter A lead spacing .220 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter A lead spacing .220 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter A lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter A lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter B lead spacing .220 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. IR transmissive polysulfone discrete shells. Electrical parameter B lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter C lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .010 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter C lead spacing .220 inches. Aperture in front of sensor .050 inches. Aperture in front of emitter .050 inches. Slotted optical switch phototransistor output. Opaque polysulfone discrete shells. Electrical parameter B lead spacing .220 inches. Aperture in front of sensor .010 inches. Aperture in front of emitter .050 inches.
|
Optek Technology
|
ACC701-000 |
10/100Mb/s Electrical-to-Electrical Ethernet Demarcation Device.
|
JDS Uniphase Corporation
|
KTS1C1S250 |
Typical RDS(on) (N-Channel)=0.9 Typical RDS(on) (N-Channel)=2.1 Gate-source zener diode
|
TY Semiconductor Co., Ltd
|
MPX2200 MPX2200A MPX2200AP MPX2200AS MPX2200D MPX2 |
0 to 200 kPa (0 to 29 psi) 40 mV FULL SCALE SPAN (TYPICAL) 000千帕29 PSI)的全尺寸为40 mV跨度(典型) 0 to 200 kPa (0 to 29 psi) 40 mV FULL SCALE SPAN (TYPICAL) 000千帕9 PSI)的全尺寸为40 mV跨度(典型) (MPX2200 / MPX2201) 0 to 200 kPa (0 to 29 psi) 40 mV FULL SCALE SPAN (TYPICAL)
|
Motorola Mobility Holdings, Inc. Motorola, Inc. MOTOROLA[Motorola Inc] MOTOROLA[Motorola, Inc]
|
FMCE-0528 FMCE-0528-TR |
Attenuation to 60 dB at 500 kHz, typical Operating temperature -55掳 to 125掳C Attenuation to 60 dB at 500 kHz, typical Operating temperature -55° to 125°C
|
Interpoint Corporation Company
|
MCP6542 MCP6542-I/MS MCP6542-I/P MCP6542-I/SN MCP6 |
The MCP6544 is a Push-pull, quad comparator. This single-ended device operates from 1.6V to 5.5V,with typical quiescent current of ... The MCP6541 is a Push-pull, single comparator. This single-ended device operates from 1.6V to 5.5V, with typical quiescent current ... Push-Pull Output Sub-Microamp Comparators The MCP6544 is a Push-pull, quad comparator. This single-ended device operates from 1.6V to 5.5V, with typical quiescent current of 600 nA and a maximum of 1 microamp. This device is offered in the 16 lead PDIP, SOIC and 14 lead TSSOP pack The MCP6543 is a Push-pull, single comparator. This single-ended device operates from 1.6V to 5.5V, with typical quiescent current of 600 nA and a maximum of 1 microamp. This device is offered in the eight lead PDIP, SOIC and MSOP package, The MCP6542 is a Push-pull, dual comparator. This single-ended device operates from 1.6V to 5.5V, with typical quiescent current of 600 nA and a maximum of 1 microamp. This device is offered in the eight lead PDIP, SOIC and MSOP package. The MCP6541 is a Push-pull, single comparator. This single-ended device operates from 1.6V to 5.5V, with typical quiescent current of 600 nA and a maximum of 1 microamp. This device is offered in the eight lead PDIP, SOIC, MSOP and five le The MCP6543 is a Push-pull, single comparator. This single-ended device operates from 1.6V to 5.5V,with typical quiescent current ... The MCP6542 is a Push-pull, dual comparator. This single-ended device operates from 1.6V to 5.5V,with typical quiescent current of ... From old datasheet system IC,VOLT COMPARATOR,DUAL,CMOS,TSSOP,8PIN,PLASTIC
|
Microchip Technology Inc.
|
HEDS-5500I11 HEDM-5505B04 HEDS-5500F02 HEDM-5500 |
Quick Assembly Two and Three Channel Optical Encoders SINGLE, 2 CHANNELS, ROTARY OPTICAL POSITION ENCODER
|
AVAGO TECHNOLOGIES LIMI...
|
ADNS-2001 HDNS-2200 HLMP-ED80 ADNB-2013 ADNB-2012 |
Optical Mouse Sensor 光学鼠标传感 HDNS-2100 · Solid-State Optical Mouse lens ADNS-2001 · Optical Mouse Sensor HLMP-ED80 · AllnGaP II LED Lamps for Sensor-Based Applications HDNS-2200 · Solid-State Optical Mouse LED Assembly Clip
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Avago Technologies, Ltd. Agilent Technologies, Inc. Agilent (Hewlett-Packard) HP[Agilent(Hewlett-Packard)]
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