10 Terminals 2.5V 10-Pin TPS62000 DC DC Voltage Regulator SWITCHING REGULATOR 1 Outputs 750kHz Tube 10-TFSOP, 10-MSOP (0.118, 3.00mm Width)
It is designed to provide optimal performance by utilizing the Tube package. There are 10 terminations in this harley voltage regulator. As this regulator voltage is equipped with an analog IC of the type SWITCHING REGULATOR, it is a SWITCHING REGULATOR-type voltage regulator. For space-saving purposes, this voltage regulator is available in the 10-TFSOP, 10-MSOP (0.118, 3.00mm Width) package. A total of 1 outputs are configured in this voltage regulator. On the output pins of this DC DC switching regulator, there is a Adjustable output generated. Surface Mount-mount switching regulator. -40°C~85°C TA should be the operating temperature when voltage regulator is operating. Voltage regulator's switching frequency reaches 750kHz. The voltage regulator can be operated with a voltage as low as 2.5V as an input voltage. According to the table below, DC DC switching regulator's output voltage (Min/Fixed) is equal to 0.8V. With its peak reflow temperature of 260, this voltage regulator is essentially indestructible. To meet the operation requirements, voltage regulator is designed to provide 3.6V as the nominal input voltage. In this case, the DC/DC regulator belongs to the family TPS62000. Voltage can be produced at 5.5V volts by voltage regulator. The switching regulator operation of the system is controlled by 10 pins. In order to use this voltage regulator 12v at its full potential, the output voltage should be kept at at least 900mV. A maximum output current of 600mA A is available to meet the switching regulator operation requirements. The maximum voltage of voltage regulator 12v DC DC switching regulator can produce is 5V, which is the highest available. An input voltage of 5.5V is used to operate this harley voltage regulator. No external factors affect how much current harley voltage regulator consumes. Switching regulators with PFM CONTROL TECHNIQUE IS ALSO POSSIBLE features are highly efficient and stable.