| No. |
Part Name |
Description |
Manufacturer |
| 91 |
AN1473 |
HOW TO USE THE WRITE TO BUFFER FEATURE OF THE M58LW064 FAMILY OF FLASH MEMORIES |
SGS Thomson Microelectronics |
| 92 |
AN1536 |
DESIGNING APPLICATIONS THAT WORK WITH ANY M25PXX DEVICE TAKING ADVANTAGE OF THEIR HARDWARE AND SOFTWARE COMPATIBILITY |
SGS Thomson Microelectronics |
| 93 |
AN16 |
Jitter Attenuation Performance of the CS61575 and CS61575A |
Cirrus Logic |
| 94 |
AN1943 |
Improving the Performance of the MAX4455 by Reducing On-Screen Display Artifacts |
MAXIM - Dallas Semiconductor |
| 95 |
AN307 |
USE OF TRIACS ON INDUCTIVE LOADS |
SGS Thomson Microelectronics |
| 96 |
AN450 |
PC BASED DEVOLOPMENT SYSTEM CUTS DESIGN TIME OF SMART POWER IC APPLICATION |
SGS Thomson Microelectronics |
| 97 |
AN48820A |
Low current consumption, high sensitivity CMOS Hall IC Operate by the value of magnetic flux density, regardless of polarity |
Panasonic |
| 98 |
AN48830B |
Low current consumption, high sensitivity CMOS Hall IC Operate by the value of magnetic flux density, regardless of polarity |
Panasonic |
| 99 |
AN509 |
INFLUENCE OF GATE AND BASE DRIVE ON POWER SWITCH BEHAVIOUR |
SGS Thomson Microelectronics |
| 100 |
AN554 |
CHOICE OF PROTECTION IN AUTOMOTIVE APPLICATIONS |
SGS Thomson Microelectronics |
| 101 |
AN586 |
USE OF TRANSIL AS RECTIFIER DIODES |
SGS Thomson Microelectronics |
| 102 |
AN647 |
HOW TO TEST OUTPUT RIPPLE AND NOISE OF POWER SUPPLIES |
SGS Thomson Microelectronics |
| 103 |
AN731 |
Simple Solution for Dynamically Programming the Output Voltage of DC-DC Converters |
Vishay |
| 104 |
APPLICATION NOTE |
Extending the range of an intermodulation distortion test |
Motorola |
| 105 |
APPLICATION NOTE 1025 |
Realiability considerations in design and use of RF integrated circuits |
Motorola |
| 106 |
APPLICATION-NOTE |
The use of safe operating area |
NEC |
| 107 |
APPLICATION-NOTE |
Optimum method of use of low frequency low noise transistors |
NEC |
| 108 |
APPLICATION-NOTE |
Example of 3W pure complementary OTL audio power amplifier circuit using JE9000 series |
NEC |
| 109 |
ASZ15 |
Application Note - Example of Static Converter |
COMPELEC |
| 110 |
ASZ16 |
Application Note - Example of Static Converter |
COMPELEC |
| 111 |
ASZ17 |
Application Note - Example of Static Converter |
COMPELEC |
| 112 |
ASZ18 |
Application Note - Example of Static Converter |
COMPELEC |
| 113 |
AT43USB380 |
On-The-Go Upgrade of the AT43USB370 USB 2.0 Full-Speed Host/Function Processor. The AT43USB380 provides three modes of operation: ... |
Atmel |
| 114 |
AT61162E |
Radiation Hard 2Mbit x 8 SRAM Cube. Made of 16 stacked 128K x 8 SRAMs. |
Atmel |
| 115 |
AT75C140 |
This Smart Internet Appliance Processor is a high-performance processor specially designed for network-enabling consumer and industrial applications. The specific architecture of this device delivers unmatched performance for low power con |
Atmel |
| 116 |
AT86RF401 |
Smart RF Wireless Data Transmitter. Highly integrated, low-cost RF transmitter, combined with an AVR RISC Microcontroller. RF Frequency Range of 250-450 MHz |
Atmel |
| 117 |
ATC18 |
The ATC18 Cell-based ASIC (CBIC) family features a comprehensive library of 0.18-micron standard logic and I/O cells designed to operate with a supply voltage of 1.8V +/- 0.15V and memory cells compiled to the precise requirements of the d |
Atmel |
| 118 |
ATC20 |
The ATC20 Cell-based ASIC (CBIC) family features a comprehensive library of 0.21-micron standard logic and I/O cells designed to operate with a supply voltage of 1.8V +/- 0.15V and memory cells compiled to the precise requirements of the d |
Atmel |
| 119 |
ATC25 |
The ATC25 Cell-based ASIC (CBIC) family features a comprehensive library of 0.25-micron standard logic and I/O cells designed to operate with a supply voltage of 2.5V +/- 0.25V and memory cells compiled to the precise requirements of the d |
Atmel |
| 120 |
ATC35 |
The ATC35 Cell-based ASIC (CBIC) family features a comprehensive library of 0.35-micron standard logic and I/O cells designed to operate with a supply voltage of 3.3V +/- 0.3V and memory cells compiled to the precise requirements of the de |
Atmel |
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