| No. |
Part Name |
Description |
Manufacturer |
| 1801 |
TB62715FN |
8 bit constant current LED source driver with shift register and latch functions. |
Marktech Optoelectronics |
| 1802 |
TB62715FN |
8 BIT SHIFT REGISTER, LATCHES & CONSTANT CURRENT DRIVERS |
TOSHIBA |
| 1803 |
TB62716F |
16 BIT SHIFT REGISTER, LATCHES & CONSTANT CURRENT DRIVERS |
TOSHIBA |
| 1804 |
TB62717F |
24 BIT CONSTANT CURRENT DRIVERS (3 x 8 BIT SHIFT REGISTER & LATCH) |
TOSHIBA |
| 1805 |
TB62717N |
24 BIT CONSTANT CURRENT DRIVERS (3 x 8 BIT SHIFT REGISTER & LATCH) |
TOSHIBA |
| 1806 |
TB62725 |
8 bit constant current LED driver O, operating voltage 3.3V. |
Marktech Optoelectronics |
| 1807 |
TB62725F |
8-bit Constant-Current LED Driver with Operating Voltage of 3.3 V |
TOSHIBA |
| 1808 |
TB62725FN |
8-bit Constant-Current LED Driver with Operating Voltage of 3.3 V |
TOSHIBA |
| 1809 |
TB62725N |
8 bit constant current LED driver O, operating voltage 3.3V. |
Marktech Optoelectronics |
| 1810 |
TB62725P |
8 bit constant current LED driver O, operating voltage 3.3V. |
Marktech Optoelectronics |
| 1811 |
TB62725P |
8-bit Constant-Current LED Driver with Operating Voltage of 3.3 V |
TOSHIBA |
| 1812 |
TB62726F |
16-bit constant current LED driver with operating voltage of 3.3V. |
Marktech Optoelectronics |
| 1813 |
TB62726F |
16-bit Constant-Current LED Driver with Operating Voltage of 3.3 V |
TOSHIBA |
| 1814 |
TB62726N |
16-bit constant current LED driver with operating voltage of 3.3V. |
Marktech Optoelectronics |
| 1815 |
TB62726N |
16-bit Constant-Current LED Driver with Operating Voltage of 3.3 V |
TOSHIBA |
| 1816 |
TC1014 |
The TC1014, TC1015, and TC1185 are high accuracy (typically ±0.5%) CMOS upgrades for older (bipolar) low dropout regulators such as the LP2980. Designed specifically for battery-operated systems, the devices’ CMOS construction e |
Microchip |
| 1817 |
TC1015 |
The TC1014, TC1015, and TC1185 are high accuracy (typically ±0.5%) CMOS upgrades for older (bipolar) low dropout regulators such as the LP2980. Designed specifically for battery-operated systems, the devices’ CMOS construction e |
Microchip |
| 1818 |
TC1030 |
The TC1030 is a quad CMOS operational amplifier designed for low power applications. It has a typical operating supply current of 20 �A, which is constant over the supply voltage range of 1.8 to 5.5 V. Each op amp has rail-to-rail inputs a |
Microchip |
| 1819 |
TC1034 |
The TC1034 is a single CMOS operational amplifier (op amp) for low-power applications. It has a typical operating supply current of 6 �A, which is constant over the supply voltage range of 1.8 to 5.5 V. The op amp has a rail-to-rail input |
Microchip |
| 1820 |
TC1035 |
The TC1035 is a single CMOS operational amplifier for low-power applications. It has a typical operating supply current of 6 �A, which is constant over the supply voltage range of 1.8 to 5.5 V. The op amp has a rail-to-rail input and outpu |
Microchip |
| 1821 |
TC1054 |
The TC1054, TC1055, and TC1186 are high accuracy (typically ±0.5%) CMOS upgrades for older (bipolar) low dropout regulators. Designed specifically for battery-operated systems, the devices’ CMOS construction eliminates wasted gr |
Microchip |
| 1822 |
TC1055 |
The TC1054, TC1055, and TC1186 are high accuracy (typically ±0.5%) CMOS upgrades for older (bipolar) low dropout regulators. Designed specifically for battery-operated systems, the devices’ CMOS construction eliminates wasted gr |
Microchip |
| 1823 |
TC1072 |
The TC1072 and TC1073 are high accuracy (typically ±0.5%) CMOS upgrade for older (bipolar) low dropout regulators. Designed specifically for battery-operated systems, the devices’ CMOS construction eliminates wasted ground curre |
Microchip |
| 1824 |
TC1073 |
The TC1072 and TC1073 are high accuracy (typically ±0.5%) CMOS upgrade for older (bipolar) low dropout regulators. Designed specifically for battery-operated systems, the devices’ CMOS construction eliminates wasted ground curre |
Microchip |
| 1825 |
TC1185 |
The TC1014, TC1015, and TC1185 are high accuracy (typically ±0.5%) CMOS upgrades for older (bipolar) low dropout regulators such as the LP2980. Designed specifically for battery-operated systems, the devices’ CMOS construction e |
Microchip |
| 1826 |
TC1186 |
The TC1054, TC1055, and TC1186 are high accuracy (typically ±0.5%) CMOS upgrades for older (bipolar) low dropout regulators. Designed specifically for battery-operated systems, the devices’ CMOS construction eliminates wasted gr |
Microchip |
| 1827 |
TC1223 |
The TC1223 and TC1224 are high accuracy (typically ±0.5%) CMOS upgrade for older (bipolar) low dropout regulators such as the LP2980. Designed specifically for battery-operated systems, the devices CMOS constructio neliminates wasted |
Microchip |
| 1828 |
TC1224 |
The TC1223 and TC1224 are high accuracy (typically ±0.5%) CMOS upgrade for older (bipolar) low dropout regulators such as the LP2980. Designed specifically for battery-operated systems, the devices CMOS constructio neliminates wasted |
Microchip |
| 1829 |
TC1262 |
The TC1262 is a fixed output, high accuracy (typically ±0.5%) CMOS low dropout regulator. Designed specifically for battery-operated systems, the TC1262’s CMOS construction eliminates wasted ground current, significantly extendi |
Microchip |
| 1830 |
TC1263 |
The TC1263 is a fixed output, high accuracy (typically ±0.5%) CMOS low dropout regulator. Designed specifically for battery-operated systems, the TC1263’s CMOS construction eliminates wasted ground current, significantly extendi |
Microchip |
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