5-Pin 關P Supervisory Circuits with Watchdog and Manual Reset

General Description The MAX6316–MAX6322 family of microprocessor (µP) supervisory circuits monitors power supplies and microprocessor activity in digital systems. It offers several combinations of push/pull, open-drain, and bidirectional (such as Motorola 68HC11) reset outputs, along with watchdo

5-Pin 關P Supervisory Circuits with Watchdog and Manual Reset

General Description The MAX6316–MAX6322 family of microprocessor (µP) supervisory circuits monitors power supplies and microprocessor activity in digital systems. It offers several combinations of push/pull, open-drain, and bidirectional (such as Motorola 68HC11) reset outputs, along with watchdo

5-Pin 關P Supervisory Circuits with Watchdog and Manual Reset

General Description The MAX6316–MAX6322 family of microprocessor (µP) supervisory circuits monitors power supplies and microprocessor activity in digital systems. It offers several combinations of push/pull, open-drain, and bidirectional (such as Motorola 68HC11) reset outputs, along with watchdo

5-Pin 關P Supervisory Circuits with Watchdog and Manual Reset

General Description The MAX6316–MAX6322 family of microprocessor (µP) supervisory circuits monitors power supplies and microprocessor activity in digital systems. It offers several combinations of push/pull, open-drain, and bidirectional (such as Motorola 68HC11) reset outputs, along with watchdo

5-Pin 關P Supervisory Circuits with Watchdog and Manual Reset

General Description The MAX6316–MAX6322 family of microprocessor (µP) supervisory circuits monitors power supplies and microprocessor activity in digital systems. It offers several combinations of push/pull, open-drain, and bidirectional (such as Motorola 68HC11) reset outputs, along with watchdo

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

1ppm/째C, Low-Noise, 2.5V/4.096V/5V Voltage References

General Description The MAX6325/MAX6341/MAX6350 are low-noise, precision voltage references with extremely low, 0.5ppm/°C typical temperature coefficients and excellent, ±0.02 initial accuracy. These devices feature buried-zener technology for lowest noise performance. Load-regulation specificati

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

Quad Voltage Monitor in 關MAX Package

General Description The MAX6338 quad voltage monitor is capable of monitoring up to four supplies without any external components. A variety of factory-trimmed threshold voltages and supply tolerances are available to optimize the MAX6338 for specific applications. The selection includes input op

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

CMOS Fixed/Adjustable Output Step-Up Switching Regulators

1ppm/째C, Low-Noise, 2.5V/4.096V/5V Voltage References

General Description The MAX6325/MAX6341/MAX6350 are low-noise, precision voltage references with extremely low, 0.5ppm/°C typical temperature coefficients and excellent, ±0.02 initial accuracy. These devices feature buried-zener technology for lowest noise performance. Load-regulation specificati

1ppm/째C, Low-Noise, 2.5V/4.096V/5V Voltage References

General Description The MAX6325/MAX6341/MAX6350 are low-noise, precision voltage references with extremely low, 0.5ppm/°C typical temperature coefficients and excellent, ±0.02 initial accuracy. These devices feature buried-zener technology for lowest noise performance. Load-regulation specificati

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs

Dual/Triple-Voltage 關P Supervisory Circuits

General Description The MAX6351–MAX6360 microprocessor (µP) supervisors with multiple reset voltages significantly improve system reliability and accuracy compared to separate ICs or discrete components. If any input supply voltage drops below its associated preset threshold, all reset outputs