GD32F307VGT6 LQFP-100(14x14) Arm® Cortex®-M4 32-bit MCU

GD32F307VGT6 vs. STM32F417VGT6: Enhanced Performance and Efficiency

The GD32F307VGT6 operates at a 168 MHz Cortex-M3 core, providing a strong balance of performance and energy efficiency. In comparison, the STM32F417VGT6 also features a 168 MHz Cortex-M4 core, but the GD32F307VGT6 outperforms it in terms of power efficiency due to its optimized architecture. This makes the GD32F307VGT6 a better choice for power-sensitive applications such as IoT devices and portable electronics, where lower energy consumption is crucial.

In terms of memory, the GD32F307VGT6 offers 512 KB Flash and 128 KB SRAM, which is comparable to the STM32F417VGT6's 512 KB Flash and 128 KB SRAM. However, the GD32F307VGT6 excels in offering more advanced peripheral sets, including USB 2.0, CAN, I2C, and SPI, allowing for greater flexibility and connectivity in industrial control and automotive applications, where STM32F417VGT6 has fewer integrated peripherals in comparison.

The GD32F307VGT6 is also more cost-effective while maintaining competitive performance, which can be crucial for large-scale manufacturing and deployment of embedded systems.

GD32F307VGT6 vs. STM32F439VGT6: Superior Peripheral Support and Power Efficiency

The GD32F307VGT6 stands out against the STM32F439VGT6 by offering similar 168 MHz clock speed but with superior power management features. The STM32F439VGT6, though it features a Cortex-M4 core with enhanced DSP instructions, has a higher power consumption in comparable use cases due to its higher processing capabilities that are not always needed in lower complexity tasks.

Both chips are equipped with 512 KB Flash and 128 KB SRAM, but the GD32F307VGT6 offers more comprehensive peripheral support, such as USB 2.0, CAN, I2C, and SPI, making it a better fit for applications requiring a wide range of connectivity options. The STM32F439VGT6 is better suited for applications that need floating point operations and advanced DSP functionality, but for most embedded control applications, the GD32F307VGT6 provides a better overall value with its enhanced power efficiency and flexible peripherals.

The GD32F307VGT6's optimized low-power modes make it the preferred option for battery-powered devices, while the STM32F439VGT6 might require more power management solutions to achieve comparable battery life in such scenarios.

GD32F307VGT6 vs. STM32F413VGT6: Balanced Performance with Greater Cost-Effectiveness

In comparison with the STM32F413VGT6, the GD32F307VGT6 offers 168 MHz processing power, on par with the STM32F413VGT6's 180 MHz Cortex-M4 core. However, the GD32F307VGT6 has a clear advantage in terms of cost-effectiveness while maintaining similar performance for many applications. The STM32F413VGT6 may offer more processing power, but this comes with higher costs and power consumption, making the GD32F307VGT6 a better choice for price-sensitive applications without compromising on performance.

Both chips come with 512 KB Flash and 128 KB SRAM, making them similar in terms of memory. The GD32F307VGT6 has an edge in terms of peripheral integration, offering more interfaces and greater flexibility for industrial automation, consumer electronics, and sensor networks.

For developers looking for an efficient, high-performance solution without the premium price tag, the GD32F307VGT6 is a more attractive option than the STM32F413VGT6.

GD32F307VGT6 vs. MK64FN1M0VLL12: Versatile Features and Low Power Consumption

The GD32F307VGT6 offers an advantage over the MK64FN1M0VLL12, which features a 120 MHz Cortex-M4 core. The GD32F307VGT6's 168 MHz clock speed delivers faster processing speeds, making it better suited for applications that require higher computational performance, such as real-time systems and advanced motor control.

While the MK64FN1M0VLL12 has a 512 KB Flash and 128 KB SRAM, the GD32F307VGT6 benefits from optimized low-power operation, giving it better power efficiency, crucial for battery-operated and energy-constrained devices. Moreover, the GD32F307VGT6 comes with USB 2.0, CAN, I2C, and SPI peripherals, offering more connectivity options than the MK64FN1M0VLL12, which lacks the full suite of advanced interfaces found in the GD32F307VGT6.

In addition to its higher performance and superior peripheral support, the GD32F307VGT6 also boasts a more competitive pricing structure, offering a highly effective solution without the higher cost of the MK64FN1M0VLL12, making it a strong contender in both consumer electronics and industrial markets.

Conclusion: GD32F307VGT6 as the Leading Solution

When compared with the STM32F417VGT6, STM32F439VGT6, STM32F413VGT6, and MK64FN1M0VLL12, the GD32F307VGT6 offers a clear edge in terms of performance, peripheral integration, and power efficiency. With its 168 MHz Cortex-M3 core, a full suite of peripherals, and efficient power management, it is an ideal choice for a broad range of embedded systems, from industrial automation to automotive electronics and IoT applications.

The GD32F307VGT6 delivers high performance at a competitive price point, making it an attractive alternative to higher-priced chips like the STM32F439VGT6 and MK64FN1M0VLL12, without sacrificing important features such as advanced connectivity and energy efficiency.