| No. |
Part Name |
Description |
Manufacturer |
| 121 |
MNDS26F32MJR-QML |
QUAD DIFFERENTIAL LINE RECEIVERS ALSO AVAILABLE GUARANTEED TO 100K RAD(Si) TESTED TO MIL-STD-883, METHOD 1019.5, CONDITION A |
National Semiconductor |
| 122 |
MNDS26F32MJRQMLV |
QUAD DIFFERENTIAL LINE RECEIVERS ALSO AVAILABLE GUARANTEED TO 100K RAD(Si) TESTED TO MIL-STD-883, METHOD 1019.5, CONDITION A |
National Semiconductor |
| 123 |
MNDS26F32MW-QMLV |
QUAD DIFFERENTIAL LINE RECEIVERS ALSO AVAILABLE GUARANTEED TO 100K RAD(Si) TESTED TO MIL-STD-883, METHOD 1019.5, CONDITION A |
National Semiconductor |
| 124 |
MNDS26F32MW/883 |
QUAD DIFFERENTIAL LINE RECEIVERS ALSO AVAILABLE GUARANTEED TO 100K RAD(Si) TESTED TO MIL-STD-883, METHOD 1019.5, CONDITION A |
National Semiconductor |
| 125 |
MNDS26F32MWG/883 |
QUAD DIFFERENTIAL LINE RECEIVERS ALSO AVAILABLE GUARANTEED TO 100K RAD(Si) TESTED TO MIL-STD-883, METHOD 1019.5, CONDITION A |
National Semiconductor |
| 126 |
MNDS26F32MWGRQMLV |
QUAD DIFFERENTIAL LINE RECEIVERS ALSO AVAILABLE GUARANTEED TO 100K RAD(Si) TESTED TO MIL-STD-883, METHOD 1019.5, CONDITION A |
National Semiconductor |
| 127 |
MNDS26F32MWR-QML |
QUAD DIFFERENTIAL LINE RECEIVERS ALSO AVAILABLE GUARANTEED TO 100K RAD(Si) TESTED TO MIL-STD-883, METHOD 1019.5, CONDITION A |
National Semiconductor |
| 128 |
MNDS26F32MWRQMLV |
QUAD DIFFERENTIAL LINE RECEIVERS ALSO AVAILABLE GUARANTEED TO 100K RAD(Si) TESTED TO MIL-STD-883, METHOD 1019.5, CONDITION A |
National Semiconductor |
| 129 |
MRLM111 |
Total supply voltage: 36V; negative V.: -30V; positiveV: +30V; voltage comparator: also available guaranteed to 30k rd (Si) tested to MIL-STD-883, method 1019 |
National Semiconductor |
| 130 |
NC921 |
NPN medium power UHF-VHF transistor (This datasheet of NE416 series is also the datasheet of NC921, see the Electrical Characteristics table) |
NEC |
| 131 |
PIC18F2439 |
The PIC18F2439 merges all the advantages of the PIC18F architecture and the flexibility of FLASH program memory with a sophisticated motor control kernel targeted for single phase induction motor control applications. The PIC18F2439 also f |
Microchip |
| 132 |
PIC18F2539 |
The PIC18F2539 merges all the advantages of the PIC18F architecture and the flexibility of FLASH program memory with a sophisticated motor control kernel targeted for single phase induction motor control applications. The PIC18F2539 also f |
Microchip |
| 133 |
PIC18F4439 |
The PIC18F4439 merges all the advantages of the PIC18F architecture and the flexibility of FLASH program memory with a sophisticated motor control kernel targeted for single phase induction motor control applications. The PIC18F4439 also f |
Microchip |
| 134 |
PIC18F4539 |
The PIC18F4539 merges all the advantages of the PIC18F architecture and the flexibility of FLASH program memory with a sophisticated motor control kernel targeted for single phase induction motor control applications. The PIC18F4539 also f |
Microchip |
| 135 |
PIC18F6520 |
The PIC18F6520 is the natural extension of the PIC18F452 device, providing more RAM, more I/Os, a second serial communication port (as well as more timers and CCP modules)on top of the same peripheral set. It is also upwards software compa |
Microchip |
| 136 |
PIC18F8520 |
The PIC18F8520 is the natural extension of the PIC18F452 device, providing more RAM, more I/Os, a second serial communication port (as well as more timers and CCP modules)on top of the same peripheral set. It is also upwards software compa |
Microchip |
| 137 |
TC1029 |
The TC1029 is a dual, CMOS operational amplifier designed for low-power applications. It is designed specifically for operation from a single supply, however, operation from dual supplies is also possible, and the power supply current drai |
Microchip |
| 138 |
TC1031 |
The TC1031 is a low-power comparator and voltage reference designed specifically for low-power applications. The TC1031 is designed for operation from a single supply, however operation from dual supplies also is possible. The power supply |
Microchip |
| 139 |
TC1037 |
The TC1037/1038/1039 are single, low-power comparators designed for low-power applications. These comparators are specifically designed for operation from a single supply. However, operation from dual supplies also is possible, and power s |
Microchip |
| 140 |
TC1038 |
The TC1037/1038/1039 are single, low-power comparators designed for low-power applications. These comparators are specifically designed for operation from a single supply. However, operation from dual supplies also is possible, and power s |
Microchip |
| 141 |
TC1039 |
The TC1037/1038/1039 are single, low-power comparators designed for low-power applications. These comparators are specifically designed for operation from a single supply. However, operation from dual supplies also is possible, and power s |
Microchip |
| 142 |
TCN75 |
The TCN75 is a serially programmable temperature sensor that notifies the host controller when ambient temperature exceeds a user-programmed setpoint. Hysteresis is also programmable. The INT/CMPTR output is programmable as either a simple |
Microchip |
| 143 |
WS512K16-17DLC |
17ns; 5V power supply - 3.3V parts also available; 512K x 16 SRAM module |
White Electronic Designs |
| 144 |
WS512K16-17DLCA |
17ns; 5V power supply - 3.3V parts also available; 512K x 16 SRAM module |
White Electronic Designs |
| 145 |
WS512K16-17DLI |
17ns; 5V power supply - 3.3V parts also available; 512K x 16 SRAM module |
White Electronic Designs |
| 146 |
WS512K16-17DLIA |
17ns; 5V power supply - 3.3V parts also available; 512K x 16 SRAM module |
White Electronic Designs |
| 147 |
WS512K16-17DLM |
17ns; 5V power supply - 3.3V parts also available; 512K x 16 SRAM module |
White Electronic Designs |
| 148 |
WS512K16-17DLMA |
17ns; 5V power supply - 3.3V parts also available; 512K x 16 SRAM module |
White Electronic Designs |
| 149 |
WS512K16-17FLCA |
17ns; 5V power supply - 3.3V parts also available; 512K x 16 SRAM module |
White Electronic Designs |
| 150 |
WS512K16-17FLI |
17ns; 5V power supply - 3.3V parts also available; 512K x 16 SRAM module |
White Electronic Designs |
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