No. |
Part Name |
Description |
Manufacturer |
1 |
1N4001 |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
2 |
1N4001G |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
3 |
1N4002 |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
4 |
1N4002G |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
5 |
1N4003 |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
6 |
1N4003G |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
7 |
1N4004 |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
8 |
1N4004G |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
9 |
1N4005 |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
10 |
1N4005G |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
11 |
1N4006 |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
12 |
1N4006G |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
13 |
1N4007 |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
14 |
1N4007G |
Rectifiers(Rugged glass package, using a high temperature alloyed construction) |
Philips |
15 |
AN1019 |
SECOND SOURCE FOR 'SNAPHAT' BY USING A DUAL FOOTPRINT |
SGS Thomson Microelectronics |
16 |
AN1116 |
CHANGING FROM THE ST95P08 TO THE M95080 IN YOUR APPLICATION USING A SIMPLE SOFTWARE RECOGNITION METHOD |
SGS Thomson Microelectronics |
17 |
AN1187 |
ALL YOU NEED TO KNOW BEFORE CHOOSING A FLASH MEMORY |
SGS Thomson Microelectronics |
18 |
AN1436 |
CHANGING FROM THE ST95010/ST95020 TO THE M95010/M95020 IN YOUR APPLICATION USING A SIMPLE RECOGNITION METHOD |
SGS Thomson Microelectronics |
19 |
AN180 |
Using a PLL to Generate Clocks for Digital Audio |
Cirrus Logic |
20 |
AN51 |
Tone, Balance, and Volume Control using a Quad XDCP |
Xicor |
21 |
AN922 |
USING A SUPER CAP TO BACK UP THE M41T56 |
SGS Thomson Microelectronics |
22 |
ATL60 |
The ATL60 series CMOS Gate Arrays are fabricated using a 0.6 micron drawn gate, oxide isolated, triple level metal process. Extensive cell libraries are available and support the major CAD software tools. |
Atmel |
23 |
ATSAM2193 |
The ATSAM2193 provides a single-chip, low-cost MIDI sound system. Equipped with a serial and a parallel MIDI input, it provides state-of-the-art sound synthesis using a full GM sound set together with a range of compatible effects. Its low |
Atmel |
24 |
EVAL6226QR |
Demonstration board using a dual full-bridge L6226Q for motor control applications |
ST Microelectronics |
25 |
EVAL6227QR |
Demonstration board using a dual full-bridge L6227Q for motor control applications |
ST Microelectronics |
26 |
PCA1672 |
32 kHz watch circuits using a silver-oxide or a 3 V lithium battery |
Philips |
27 |
PCA1672U |
32 kHz watch circuits using a silver-oxide or a 3 V lithium battery |
Philips |
28 |
PCA1673 |
32 kHz watch circuits using a silver-oxide or a 3 V lithium battery |
Philips |
29 |
PCA1673U |
32 kHz watch circuits using a silver-oxide or a 3 V lithium battery |
Philips |
30 |
PCA1673U/10/F2 |
32 kHz watch circuits using a silver-oxide or a 3 V lithium battery |
Philips |
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