No. |
Part Name |
Description |
Manufacturer |
1 |
AN115 |
A Compendium of Application Circuits for Xicor's Digitally-Controlled (XDCP) Potentiometers |
Xicor |
2 |
EB4 |
Dual Readout, Standard and Right Angle Terminals, Selective Gold Plating, Polarization Between Contact Positions, Recognized Under the Component Program of Underwriters' Laboratories Inc (File E65524, Project 77CH3889) |
Vishay |
3 |
EB4 HI TEMP |
High Temp (Glass Reinforced), Dual Readout, High Reliability Copper-Nickel-Tin Alloy Contacts or Gold Contacts, Recognized Under the Component Program of Underwriters' Laboratories Inc (File E65524) |
Vishay |
4 |
EB6 |
Dual Readout, Standard and Right Angle Terminals, Selective Gold Plating, Polarization Between Contact Positions, Recognized Under the Component Program of Underwriters' Laboratories Inc (File E65524, Project 77CH3889) |
Vishay |
5 |
EB6 HI TEMP |
High Temp (Glass Reinforced), Dual Readout, High Reliability Copper-Nickel-Tin Alloy Contacts or Gold Contacts, Recognized Under the Component Program of Underwriters' Laboratories Inc (File E65524) |
Vishay |
6 |
EB7 HI TEMP |
High Temp (Glass Reinforced), Dual Readout, High Reliability Copper-Nickel-Tin Alloy Contacts or Gold Contacts, Recognized Under the Component Program of Underwriters' Laboratories Inc (File E65524) |
Vishay |
7 |
EB8 |
Dual Readout, Selective Gold Plating, Polarization Between Contact Positions, Recognized Under the Component Program of Underwriters' Laboratories Inc (File E65524, Project 77CH3889) |
Vishay |
8 |
EB8 HI TEMP |
High Temp (Glass Reinforced), Dual Readout, High Reliability Copper-Nickel-Tin Alloy Contacts or Gold Contacts, Recognized Under the Component Program of Underwriters' Laboratories Inc (File E65524) |
Vishay |
9 |
LA1266 |
AM/FM Tuner System Of Electronic Tuning Type |
SANYO |
10 |
MCP6541 |
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 |
Microchip |
11 |
MCP6542 |
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. |
Microchip |
12 |
MCP6543 |
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, |
Microchip |
13 |
MCP6544 |
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 |
Microchip |
14 |
MCP6546 |
The MCP6546 is an Open-Drain, 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 and is 10V output capable. This device is offered in the eight lead |
Microchip |
15 |
MCP6547 |
The MCP6547 is an Open Drain, 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 and is 10V output capable. This device is offered in the eight lead PD |
Microchip |
16 |
MCP6548 |
The MCP6548 is an Open Drain, 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 and is 10V output capable. This device is offered in the eight lead |
Microchip |
17 |
MCP6549 |
The MCP6549 is an Open Drain, 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 and is 10V output capable. This device is offered in the sixteen lead |
Microchip |
18 |
TC125 |
The TC125/6 step-up (Boost) switching regulators furnish output currents to a maximum of 80 mA (VIN = 2V, VOUT = 3V) with typical efficiencies above 80%. These devices employ pulse frequency modulation (PFM) for minimum supply current at l |
Microchip |
19 |
TC125301ECTTR |
The TC125/6 step-up (Boost) switching regulators furnish output currents to a maximum of 80 mA (VIN = 2V, VOUT = 3V) with typical ... |
Microchip |
20 |
TC125331ECTTR |
The TC125/6 step-up (Boost) switching regulators furnish output currents to a maximum of 80 mA (VIN = 2V, VOUT = 3V) with typical ... |
Microchip |
21 |
TC125501ECTTR |
The TC125/6 step-up (Boost) switching regulators furnish output currents to a maximum of 80 mA (VIN = 2V, VOUT = 3V) with typical ... |
Microchip |
22 |
TC126 |
The TC125/6 step-up (Boost) switching regulators furnish output currents to a maximum of 80 mA (VIN = 2V, VOUT = 3V) with typical efficiencies above 80%. These devices employ pulse frequency modulation (PFM) for minimum supply current at l |
Microchip |
23 |
TC126301ECTTR |
The TC125/6 step-up (Boost) switching regulators furnish output currents to a maximum of 80 mA (VIN = 2V, VOUT = 3V) with typical ... |
Microchip |
24 |
TC126331ECTTR |
The TC125/6 step-up (Boost) switching regulators furnish output currents to a maximum of 80 mA (VIN = 2V, VOUT = 3V) with typical ... |
Microchip |
25 |
TC126501ECTTR |
The TC125/6 step-up (Boost) switching regulators furnish output currents to a maximum of 80 mA (VIN = 2V, VOUT = 3V) with typical ... |
Microchip |
26 |
TC4421 |
The TC4421/4422 are high current buffer/drivers capable of driving large MOSFETs and IGBTs. They are essentially immune to any form of upset except direct overvoltage or over-dissipation — they cannot be latched under any conditions |
Microchip |
27 |
TC4422 |
The TC4421/4422 are high current buffer/drivers capable of driving large MOSFETs and IGBTs. They are essentially immune to any form of upset except direct overvoltage or over-dissipation — they cannot be latched under any conditions |
Microchip |
28 |
TC7652 |
The TC7652 is a lower noise version of the TC7650, sacrificing some input specifications (bias current and bandwidth)to achieve a 10x reduction in noise.All the other benefits of the chopper technique are present,i.e.freedom from offset ad |
Microchip |
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