Catalog(4 parts)
| Part | Voltage - Supply (Vcc/Vdd)▲▼ | Voltage - Supply (Vcc/Vdd)▲▼ | Supplier Device Package | Package / Case▲▼ | Package / Case | Package / Case▲▼ | Mounting Type | Interface | Operating Temperature▲▼ | Operating Temperature▲▼ | Output Configuration | Output Type | Ratio - Input:Output | Input Type | Switch Type | Number of Outputs▲▼ | Voltage - Load▲▼ | Current - Output (Max)▲▼ | Package / Case▲▼ | Supplied Contents | Utilized IC / Part | Function | Type |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
8.5 V | 40 V | 16-TSSOP | 0.004394200164824724 m | 16-TSSOP | 0.004399999976158142 m | Surface Mount | Parallel | -40 °C | 125 °C | Low Side | N-Channel | 1:1 | CMOS | Relay, Solenoid Driver | 7 ul | 40 V | 0.5 A | ||||||
6.5 V | 30 V | 16-TSSOP | 0.004394200164824724 m | 16-TSSOP | 0.004399999976158142 m | Surface Mount | Parallel | -40 °C | 125 °C | Low Side | N-Channel | 1:1 | CMOS | Relay, Solenoid Driver | 7 ul | 30 V | 0.5 A | ||||||
6.5 V | 30 V | 16-SOIC | 16-SOIC | Surface Mount | Parallel | -40 °C | 125 °C | Low Side | N-Channel | 1:1 | CMOS | Relay, Solenoid Driver | 7 ul | 30 V | 0.5 A | 0.003911599982529879 m, 3.900000095367432 ul | |||||||
Texas Instruments TPL7407LEVMTPL7407L Low Side Driver (External FET) Power Management Evaluation Board | Board(s) | TPL7407L | Low Side Driver (External FET) | Power Management |
Key Features
• 600-mA Rated Drain Current (Per Channel)CMOS Pin-to-Pin Improvement of 7-channel Darlington Array (For example: ULN2003A)Power Efficient (Very low VOL)Less Than 4 Times Lower VOLat 100 mA Than Darlington ArrayVery Low Output Leakage < 10 nA Per ChannelExtended Ambient Temperature Range:TA= –40°C to +125°CHigh-Voltage Outputs 30 VCompatible with 1.8-V to 5-V Microcontroller and Logic InterfaceInternal Free-wheeling Diodes for Inductive Kick-back ProtectionInput Pull-down Resistors Allows Tri-stating the Input DriverInput RC-Snubber to Eliminate Spurious Operation in Noisy EnvironmentInductive Load Driver ApplicationsESD Protection Exceeds JESD 222-kV HBM, 500-V CDMAvailable in 16-pin SOIC and TSSOP packages600-mA Rated Drain Current (Per Channel)CMOS Pin-to-Pin Improvement of 7-channel Darlington Array (For example: ULN2003A)Power Efficient (Very low VOL)Less Than 4 Times Lower VOLat 100 mA Than Darlington ArrayVery Low Output Leakage < 10 nA Per ChannelExtended Ambient Temperature Range:TA= –40°C to +125°CHigh-Voltage Outputs 30 VCompatible with 1.8-V to 5-V Microcontroller and Logic InterfaceInternal Free-wheeling Diodes for Inductive Kick-back ProtectionInput Pull-down Resistors Allows Tri-stating the Input DriverInput RC-Snubber to Eliminate Spurious Operation in Noisy EnvironmentInductive Load Driver ApplicationsESD Protection Exceeds JESD 222-kV HBM, 500-V CDMAvailable in 16-pin SOIC and TSSOP packages
Description
AI
The TPL7407LA is a high-voltage, high-current NMOS transistor array. This device consists of seven NMOS transistors that feature high-voltage outputs with common-cathode clamp diodes for switching inductive loads. The maximum drain-current rating of a single NMOS channel is 600 mA. New regulation and drive circuitry added to give maximum drive strength across all GPIO ranges (1.8 V–5 V).The transistors can be paralleled for higher current capability.
The TPL7407LA key benefit is its improved power efficiency and lower leakage than a Bipolar Darlington Implementation. With the lower VOLthe user is dissipating less than half the power than traditional relay drivers with currents less than 250 mA per channel.
The TPL7407LA is a high-voltage, high-current NMOS transistor array. This device consists of seven NMOS transistors that feature high-voltage outputs with common-cathode clamp diodes for switching inductive loads. The maximum drain-current rating of a single NMOS channel is 600 mA. New regulation and drive circuitry added to give maximum drive strength across all GPIO ranges (1.8 V–5 V).The transistors can be paralleled for higher current capability.
The TPL7407LA key benefit is its improved power efficiency and lower leakage than a Bipolar Darlington Implementation. With the lower VOLthe user is dissipating less than half the power than traditional relay drivers with currents less than 250 mA per channel.