MAX6719AUTLTD3+T Overview
A total of 6 terminals are used to mount this power management. Packaged in a Tape & Reel (TR)-shape, IC management comes with a number of features. The purpose of this IC management is to provide you with a reference of 1 functions. Depending on the power managment ic you are looking at, you can find a total of 3 channels. As a reference, this IC power includes SOT-23-6 functions for your convenience. Compared to other Multi-Voltage Supervisor products, this PMIC has a lot of benefits to offer. According to the specification, the package's peak reflow temperature is specified to be 260. A supply voltage of 1V is used to conduct the PMIC chip. IC management conducts in a 3-voltage supply. Surface Mount mounts IC management. There is a subcategory of this power ic known as Power Management Circuits. A total of 6 pins are located on this power management. The pins of the power management system count 6. In order for this PMIC to work correctly, the minimum supply voltage (Vsup) should be greater than 800mV. Voltage (Vsup) shouldn't exceed 5.5V volts in this PMIC. Surface Mount is the recommended mounting type. The temperature of the supervisors should be set to this range: -40°C~125°C TA. When this power management system is in operation, it produces an output voltage of Open Drain or Open Collector. For this power management, there is an 15μA volt supply current. It is always advisable to use MAX6719A, the base supervisor number, when searching for similar PMICs from the manufacturer. The power management must be powered by 1/5V volts to function properly.
MAX6719AUTLTD3+T Features
Multi-Voltage Supervisor type
Minimum supply voltage of 800mV
15μA operating supply current
MAX6719AUTLTD3+T Applications
There are a lot of Maxim Integrated MAX6719AUTLTD3+T Voltage Supervisors applications.
- Precision measurement
- Detection of phase loss
- Electrical fire monitoring system
- Power communication system
- Linux and server computing
- Radio
- Solar power charger
- Stable power system
- Leakage current detection
- Magnetic resonance imaging