UCC23313QDWYRQ1


YeeHing #: Y012-UCC23313QDWYRQ1
Inventory: 4000

Feel free to reach out to us for more information.
Click the button below to unveil exclusive discounts and delightful surprises.

Description

UCC23313QDWYRQ1 Texas Instruments - Yeehing Electronics

Automotive 3.75kVrms, 4A/5A single-channel opto-compatible isolated gate driver with 8V/12V UVLO

Pricing (USD)

Quantity Unit Price
1 — 99 1.637
100 — 249 1.352
250 — 999 0.971
1,000 + 0.51

The above prices are for reference only.

Specifications

For more information, please refer to datasheet

Documents

UCC23313QDWYRQ1 Datasheet

More Information

The UCC23313-Q1 is an Opto-compatible, single-channel, isolated gate driver for IGBTs, MOSFETs and SiC MOSFETs, with 4.5-A source and 5.3-A sink peak output current and 3.75-kVRMS basic isolation rating. The high supply voltage range of 33 V allows the use of bipolar supplies to effectively drive IGBTs and SiC power FETs. UCC23313-Q1 can drive both low side and high side power FETs. Key features and characteristics bring significant performance and reliability upgrades over standard opto-coupler based gate drivers while maintaining pin-to-pin compatibility in both schematic and layout design. Performance highlights include high common mode transient immunity (CMTI), low propagation delay, and small pulse width distortion. Tight process control results in small part-to-part skew. The input stage is an emulated diode (e-diode) which means long term reliability and excellent aging characteristics compared to traditional LEDs found in optocoupler gate drivers. It is offered in a stretched SO6 package with > 8.5-mm creepage and clearance, and a mold compound from material group I, which has a comparative tracking index (CTI) > 600 V. UCC23313-Q1’s high performance and reliability makes it ideal for use in automotive motor drives such as the traction inverter, on-board chargers, DC charging stations, and automotive HVAC and heating systems. The higher operating temperature opens up opportunities for applications not previously able to be supported by traditional optocouplers.

You may also like

Recently viewed