Şirket Blog About TI LMG1020YFFR Low-Side GaN And MOSFET Driver For 1-ns Pulse Width Applications

TI LMG1020YFFR Low-Side GaN And MOSFET Driver For 1-ns Pulse Width Applications

In high-frequency power conversion, pulsed power control, and other high-end electronic applications, the demand for 1-nanosecond-level narrow pulse width driving is increasingly urgent. Traditional drivers are often constrained by parameters such as propagation delay and switching speed, making it difficult to meet the dual requirements of precise control and efficient driving. Shenzhen Mingjiada Electronics Co., Ltd. supplies/recycles TI's LMG1020YFFR low-side gate driver, specifically engineered for gallium nitride (GaN) FETs and logic-level MOSFETs. With its ultra-fast response, support for minimal pulse widths, and high reliability, it stands as the preferred component for 1-nanosecond pulse width applications. It is widely compatible with demanding fields requiring stringent timing accuracy, such as lidar (LiDAR), time-of-flight (ToF) sensing, and facial recognition where stringent timing precision is required.

I. Core Overview of LMG1020YFFR

The LMG1020YFFR is a single-channel low-side ultra-fast gate driver employing Texas Instruments' advanced driver architecture. It balances minimalist design with exceptional performance, efficiently driving both GaN FETs and silicon-based MOSFETs to achieve nanosecond-level precision control without complex peripheral circuitry. Housed in an ultra-compact DSBGA-6 (YFF) package measuring just 0.8mm × 1.2mm, it minimises gate loop inductance and reduces parasitic parameter interference during high-frequency operation. This provides the essential hardware foundation for precise timing control in 1-nanosecond pulse width applications. measuring just 0.8mm × 1.2mm. This minimises gate loop inductance and reduces parasitic parameter interference during high-frequency driving, providing the hardware foundation for precise timing control in 1-nanosecond pulse width applications. It also supports a wide operating temperature range from -40°C to 125°C, making it suitable for harsh environments across industrial and consumer electronics sectors.

LMG1020YFFR Key Parameters:

Output Current: 7 A

Supply Voltage - Min: 4.75 V

Supply Voltage - Max: 5.25 V

Rise Time: 400 ps

Fall Time: 400 ps

Minimum Operating Temperature: -40°C

Maximum Operating Temperature: +125°C

Supply current: 51 mA

Propagation delay—maximum: 4.5 ns

Unit weight: 1.200 mg

II. Core Characteristics of LMG1020YFFR

The LMG1020YFFR's core strengths lie in its ultra-high-speed response and narrow pulse support. All key parameters are specifically optimised to perfectly match the stringent requirements of 1-nanosecond pulse width applications. Specific features include:

(i) Nanosecond-Level Pulse and Ultra-Fast Switching Performance

- Minimum input pulse width as low as 1 nanosecond, enabling stable driving of power devices to achieve narrow pulse output. This satisfies timing control demands for 1-nanosecond pulse width applications, delivering outstanding performance in scenarios such as short-pulse power delivery and high-speed signal modulation. It resolves the pain points of unstable narrow pulse driving and severe distortion inherent in traditional drivers.

- Extremely rapid switching with typical rise and fall times of merely 400ps, and maximum values as low as 0.375ns and 0.35ns respectively. Minimal switching losses significantly enhance overall power system efficiency, preventing pulse distortion caused by switching delays during narrow pulse operation, thereby safeguarding pulse waveform integrity and precision.

- Exceptionally short propagation delay, with typical values of just 2.5ns and maximum values not exceeding 4.5ns. Precise timing response minimises drive signal delay errors, ensuring accurate transmission and synchronous control of 1ns pulse width signals, thereby safeguarding high-frequency timing coordination.

(2) Robust Drive Capability and Flexible Adjustment Features

The LMG1020YFFR delivers robust drive capability with 7A peak sink current (source) and 5A peak source current (drain), enabling rapid charging and discharging of GaN and MOSFET gates. This effectively overcomes gate capacitance effects, ensuring power devices achieve fast turn-on and turn-off under 1ns narrow pulse drive while preventing switching lag caused by insufficient gate drive. Additionally, it supports independent adjustment of pull-up and pull-down edge drive strength by connecting an external resistor between the gate and OUTH/OUTL pins. This accommodates GaN FETs and MOSFETs with varying parameters, enhancing device compatibility and application flexibility. Drive performance can be optimised according to the actual requirements of 1-nanosecond pulse width applications.

(3) Stable Power Supply and Comprehensive Protection Mechanisms

The LMG1020YFFR operates from a single 5V supply within a voltage range of 4.75V to 5.25V (typical 5V), delivering high supply stability. This effectively mitigates the impact of power fluctuations on drive performance, ensuring output consistency during 1-nanosecond pulse width driving. The device incorporates comprehensive protection features, including under-voltage lockout (UVLO) and over-temperature protection (OTP): The UVLO function automatically locks the driver output when the supply voltage falls below the typical value of 3.5V, preventing damage to power devices due to insufficient gate drive voltage. OTP protection activates during overheating to prevent device burnout from prolonged high-frequency, narrow-pulse operation, significantly enhancing system reliability and lifespan while reducing failure risks in 1-nanosecond pulse width applications. Additionally, the device incorporates an input filter for noise immunity, effectively suppressing external interference to maintain signal purity and prevent pulse distortion caused by disturbances.

(IV) High-Frequency Adaptability and Miniaturised Packaging Advantages

The LMG1020YFFR operates at frequencies up to 60MHz, making it suitable for high-frequency pulse drive scenarios. It aligns perfectly with the high-frequency timing demands of 1-nanosecond pulse width applications, maintaining stable operation under high-frequency cyclic narrow pulse drive modes without frequency attenuation or performance degradation. Its ultra-compact WCSP package (DSBGA-6) not only saves PCB space but also minimises gate loop inductance. This reduces parasitic parameter interference during high-frequency driving, preventing signal distortion caused by parasitic inductance. It ensures precise timing control for 1-nanosecond pulse width applications while facilitating high-density PCB layout. suiting the demands of miniaturised, integrated electronic devices such as portable LiDAR systems and micro-sensors.

III. Advantages for 1-Nanosecond Pulse Width Applications

Applications requiring 1-nanosecond pulse widths demand exceptional timing precision, switching speed, and pulse stability from drivers. Conventional drivers often suffer from excessive propagation delay, pulse distortion, and insufficient drive capability. The LMG1020YFFR, through targeted optimisation, offers distinct advantages:

1. Timing Precision Compliance: With a minimum input pulse width of 1 nanosecond and typical propagation delay of 2.5 ns, synchronisation between drive and control signals is guaranteed. This prevents pulse delay or distortion, ensuring precise output of 1-nanosecond pulse width signals. It is suitable for scenarios demanding stringent pulse timing, such as laser pulse driving and high-speed signal modulation.

2. Robust Drive Stability: With an ultra-fast 400ps switching speed and powerful 7A/5A drive capability, it rapidly responds to narrow pulse control signals. This ensures power devices complete turn-on and turn-off within extremely short durations, preventing pulse waveform distortion caused by insufficient gate charging/discharging. Consequently, it guarantees the stability and consistency of 1ns pulse width driving.

3. Streamlined System Integration: Ultra-compact packaging and minimal peripheral design eliminate the need for complex auxiliary drive circuits. This facilitates rapid integration into 1-nanosecond pulse width application systems, reducing system footprint and design complexity while mitigating parasitic parameter effects. Consequently, overall system performance is enhanced and product development cycles are shortened.

4. Outstanding Reliability: Comprehensive protection mechanisms and a wide operating temperature range accommodate the high-frequency, short-pulse drive characteristics of 1-nanosecond pulse width applications. This prevents system failures caused by device overheating or undervoltage issues, enhancing the long-term stable operation of application systems.

IV. Typical Application Scenarios for LMG1020YFFR

Leveraging its 1-nanosecond pulse width adaptation capability and ultra-high-speed drive performance, the LMG1020YFFR finds extensive application across diverse high-frequency, narrow-pulse drive scenarios. It is particularly suited to domains demanding stringent timing precision and drive efficiency, with typical applications including:

- Lidar (Light Detection and Ranging): Drives high-speed laser diodes to achieve 1-nanosecond laser pulse output, enhancing radar ranging accuracy and response speed. Suited for lidar systems in autonomous driving, industrial ranging, and security surveillance applications. Its ultra-compact packaging also meets the demands of miniaturised lidar modules.

- Time-of-Flight (ToF) Sensing: Meets the high-speed drive requirements of ToF depth sensors. Its 1-nanosecond narrow pulse drive enables precise time measurement, enhancing sensing accuracy. Applications span consumer electronics and industrial sensing scenarios such as facial recognition, 3D modelling, and smartphone unlocking.

- High-frequency power conversion: Employed in GaN-based synchronous rectifiers and VHF resonant power converters, enabling 1-nanosecond pulse width drive control to reduce switching losses and enhance conversion efficiency. Suitable for server and telecom power supplies, as well as high-efficiency 48V-to-12V/5V conversion applications.

- Other narrow-pulse applications: Includes RF envelope tracking (power modulation for 5G base station RF power amplifiers), Class D audio amplifiers, Class E wireless chargers, and augmented reality devices. Optimises overall device performance through ultra-high-speed drive capability and narrow-pulse support.

V. Summary

The TI LMG1020YFFR, a low-side GaN and MOSFET driver optimised for 1-nanosecond pulse width applications, resolves the timing distortion and insufficient drive issues inherent in traditional drivers for narrow pulse scenarios. This is achieved through its 1-nanosecond minimum input pulse width, 400ps ultra-fast switching speed, 2.5ns ultra-low propagation delay, and robust 7A/5A drive capability. Its ultra-compact package, minimalist design, and comprehensive protection mechanisms not only enhance system integration convenience and reliability but also broaden its application scope in high-end domains such as lidar, ToF sensing, and high-frequency power conversion.

With its precise timing control, efficient drive performance, and stable operation, the LMG1020YFFR stands as Texas Instruments' flagship product in the nanosecond-level drive domain. It delivers a cost-effective, highly reliable drive solution for 1-nanosecond pulse width applications, empowering engineers to rapidly develop high-performance, compact high-frequency electronic devices. This advances the implementation and evolution of high-frequency narrow-pulse drive technology.