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Comparing STM32G474RET6 and STM32G474RCT6

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Published: 24 July 2025 | Last Updated: 24 July 2025

1533

STM32G474RET6

STMicroelectronics

512KB 512K x 8 FLASH ARM® Cortex®-M4F 32-Bit Microcontroller STM32G4 Series 3V 64-LQFP

Unit Price: $3.834264

Ext Price: $3.83

Purchase Guide

512KB 512K x 8 FLASH ARM® Cortex®-M4F 32-Bit Microcontroller STM32G4 Series 3V 64-LQFP

Compare STM32G474RET6 and STM32G474RCT6 microcontrollers. Learn about differences in memory, I/O pins, and performance to choose the right one for your project.

Catalog

Product Introduction

Choosing the right microcontroller unit is essential for building reliable and efficient systems. The STM32G474RET6 and STM32G474RCT6 belong to the STM32 series, offering advanced features for diverse applications. These fast and efficient ARM microcontrollers differ in memory capacity, I/O pin configurations, and processing power. While both are part of the same family, a detailed comparison reveals how each suits specific needs. Understanding these differences helps you identify the best option for your project, whether you need higher performance or cost-effectiveness.

Specification Comparison

Core Architecture and Processing Power

The STM32G474RET6 and STM32G474RCT6 microcontrollers - mcu share the same core architecture, which is based on the ARM Cortex-M4 processor. This architecture provides a balance between performance and power efficiency, making it suitable for a wide range of applications. You benefit from the integrated floating-point unit (FPU) and digital signal processing (DSP) capabilities, which enhance computational tasks like signal filtering and data analysis.

Both microcontrollers operate with a 32-bit core processor, ensuring fast execution of instructions. However, the STM32G474RET6 offers a slightly larger package size, which may influence your choice if space constraints are a concern. The core architecture of these microcontrollers ensures compatibility with the STM32 series ecosystem, allowing you to leverage existing tools and libraries for development.

Memory (Flash and RAM)

Memory plays a crucial role in determining how much data your microcontroller can store and process. The STM32G474RET6 provides 512 KB of flash memory, while the STM32G474RCT6 offers 256 KB. If your application requires storing large amounts of code or data, the STM32G474RET6 becomes the better option. Flash memory is non-volatile, meaning it retains data even when the microcontroller is powered off.

Both models include 128 KB of RAM, which is essential for temporary data storage during runtime. This RAM capacity supports efficient multitasking and ensures smooth operation of complex algorithms. When comparing flash and RAM specifications, you should consider the size of your application and the amount of data it needs to handle.

Clock Speed and Performance

Clock speed directly impacts the performance of a microcontroller. Both the STM32G474RET6 and STM32G474RCT6 feature a maximum clock frequency of 170 MHz. This high clock speed allows you to execute instructions quickly, making these microcontrollers ideal for time-sensitive applications.

The STM32G474 series includes advanced power management features that optimize performance without consuming excessive energy. You can rely on these microcontrollers for applications requiring consistent speed and efficiency. Whether you're working on motor control, industrial automation, or signal processing, the clock speed ensures reliable operation.

Tip: When evaluating clock speed, consider the complexity of your application and whether the microcontroller's performance aligns with your requirements.

Supply Voltage and Power Consumption

When selecting a microcontroller, understanding its supply voltage and power consumption is crucial. Both the STM32G474RET6 and STM32G474RCT6 operate within a supply voltage range of 1.71V to 3.6V. This flexibility allows you to use these microcontrollers in systems with varying power requirements. Whether you're designing a battery-powered device or a system connected to a stable power source, this range ensures compatibility.

Power consumption is another important factor. Both models are designed with energy efficiency in mind. They include low-power modes that help reduce energy usage when the microcontroller is idle. These modes are especially useful in applications like IoT devices, where conserving battery life is essential. By leveraging these features, you can optimize your system's energy efficiency without compromising performance.

Operating Temperature Range

The operating temperature range determines how well a microcontroller performs under different environmental conditions. Both the STM32G474RET6 and STM32G474RCT6 are built to handle extreme temperatures, making them suitable for industrial and outdoor applications. Their temperature range spans from -40°C to 125°C, ensuring reliable operation in both freezing and high-heat environments.

Here’s a quick comparison of their temperature ranges:

Model	Operating Temperature Range (°C)
STM32G474RET6	-40.0 to 125.0
STM32G474RCT6	-40.0 to 125.0

This wide range means you can use these microcontrollers in applications like automotive systems, where temperature fluctuations are common. Whether your project involves cold storage monitoring or high-temperature machinery, these microcontrollers provide the thermal stability you need.

Tip: Always consider the environmental conditions your system will face. Choosing a microcontroller with the right temperature tolerance ensures long-term reliability.

Additional Features of STM32G474RET6 and STM32G474RCT6

I/O Pin Count and Configurations

The number of I/Os plays a critical role in determining how many external components you can connect to your microcontroller. The STM32G474RET6 offers 52 I/O pins, providing ample flexibility for complex designs. These pins support multiple configurations, allowing you to tailor them to your specific needs. Whether you’re working on motor control, sensor integration, or user interfaces, this microcontroller ensures you have enough pins to handle the job.

When planning your design, consider how many peripherals and external devices your application requires. A higher number of I/Os can simplify your circuit and reduce the need for additional components like multiplexers.

ADC Channels and Resolution

Both microcontrollers excel in data conversion capabilities. The STM32G474RET6 features 26 ADC channels with a resolution of 12 bits. This high ADC resolution ensures precise analog-to-digital conversion, making it ideal for applications like signal processing and sensor data acquisition.

In addition to ADCs, the STM32G474RET6 includes 7 DAC channels with a resolution of 12 bits. These DACs allow you to convert digital signals back into analog form, which is essential for applications like audio output or motor control. The combination of ADC and DAC features makes this microcontroller versatile for projects requiring accurate data conversion.

Tip: If your project involves sensors or analog signals, prioritize a microcontroller with high ADC and DAC resolution for better accuracy.

Connectivity Options (UART, SPI, I2C)

The STM32G474RET6 offers robust connectivity options, including UART, SPI, and I2C interfaces. These interfaces enable seamless communication with other devices, such as sensors, displays, and external memory modules. For example, the I2C interface simplifies communication with multiple devices using just two wires, while SPI provides faster data transfer for high-speed peripherals.

Additionally, this microcontroller supports advanced connectivity features like CANbus, LINbus, and QSPI. These features make it suitable for automotive, industrial, and IoT applications. Whether you need to connect to a network or communicate with multiple devices, the STM32G474RET6 ensures reliable and efficient data exchange.

Note: Evaluate your project's communication requirements to choose the right connectivity options.

Timers and PWM Capabilities

Timers play a vital role in microcontroller applications. Both the STM32G474RET6 and STM32G474RCT6 include advanced timer features that help you manage time-sensitive tasks. These microcontrollers offer multiple general-purpose timers, which you can use for counting, measuring intervals, or generating delays. They also include dedicated timers for motor control and other specialized functions.

Pulse Width Modulation (PWM) capabilities are equally impressive. PWM allows you to control the power delivered to devices like motors, LEDs, or heaters. The STM32G474RET6 provides more PWM channels compared to the STM32G474RCT6, making it a better choice for applications requiring precise control of multiple outputs. For example, you can use PWM to adjust motor speed or dim LED brightness with high accuracy.

Tip: If your project involves motor control or requires precise timing, prioritize a microcontroller with robust timer and PWM features.

Integrated Peripherals and Special Features

The STM32G474RET6 and STM32G474RCT6 come equipped with a wide range of integrated peripherals. These peripherals simplify your design by reducing the need for external components. Both models include features like USB, CANbus, and Ethernet interfaces, which enhance connectivity options for your project.

One standout feature of the STM32G474RET6 is its integrated flash memory. With 512 KB of flash, this microcontroller allows you to store larger programs and data directly on the chip. This is especially useful for applications requiring complex algorithms or extensive code libraries.

Additionally, the STM32G474RET6 includes specialized peripherals like hardware accelerators for cryptography and signal processing. These features improve performance in applications like secure communication or real-time data analysis.

Note: Evaluate your project requirements carefully. If you need more flash memory or advanced peripherals, the STM32G474RET6 offers a clear advantage.

Practical Considerations for Choosing Between STM32G474RET6 and STM32G474RCT6

Application Suitability

When deciding between the STM32G474RET6 and STM32G474RCT6, you should first evaluate your application's requirements. The STM32G474RET6, with its larger flash memory of 512 KB, is better suited for applications that demand extensive code storage or complex algorithms. For example, if you're working on advanced motor control systems or real-time data processing, this microcontroller provides the necessary resources.

On the other hand, the STM32G474RCT6, with 256 KB of flash memory, is ideal for simpler applications. If your project involves basic sensor integration or straightforward control tasks, this model offers sufficient performance without unnecessary overhead. Both microcontrollers - mcu share the same ARM Cortex-M4 processor, ensuring reliable performance across a wide range of use cases.

You should also consider the number of I/O pins and peripherals required. The STM32G474RET6, with its higher I/O pin count, is better for designs involving multiple external components. For simpler setups, the STM32G474RCT6 provides a cost-effective solution without compromising essential features.

Tip: Start by listing your project's requirements, such as memory needs, I/O pin count, and processing power. This will help you match the right microcontroller to your application.

Cost-Effectiveness

Budget constraints often play a significant role in microcontroller selection. The STM32G474RCT6 is generally more affordable due to its smaller flash memory and fewer features. If your project doesn't require the advanced capabilities of the STM32G474RET6, choosing the STM32G474RCT6 can save costs without sacrificing performance for simpler tasks.

However, the STM32G474RET6 offers better value for money in applications requiring high performance and advanced features. Its larger memory and additional peripherals justify the higher price for complex projects. For instance, if you're developing an industrial automation system or a high-precision motor control application, the STM32G474RET6 provides the resources you need to achieve optimal results.

Note: Balancing cost and functionality is key. Avoid overpaying for features you don't need, but ensure the microcontroller meets all your project requirements.

Availability and Ecosystem Support

The availability of development tools and community resources can significantly impact your project's success. Both the STM32G474RET6 and STM32G474RCT6 benefit from the extensive STM32 ecosystem, which includes development boards, software tools, and libraries. You can use tools like STM32CubeMX to simplify configuration and code generation, saving time during development.

Community support is another important factor. The STM32 series has a large user base, providing access to forums, tutorials, and example projects. This support can help you troubleshoot issues and accelerate your learning curve. Additionally, both microcontrollers offer robust connectivity options, including UART, SPI, and I2C, ensuring compatibility with a wide range of devices and systems.

When considering availability, check the supply chain for both models. The STM32G474RET6, with its advanced features, may have higher demand, potentially affecting stock levels. Planning your procurement early can help you avoid delays.

Tip: Leverage the STM32 ecosystem and community resources to streamline development. Ensure the chosen microcontroller is readily available to meet your project timeline.

Development Tools and Community Resources

When working with STM32G474RET6 and STM32G474RCT6 microcontrollers, you gain access to a rich ecosystem of development tools and community resources. These tools and resources simplify your development process, reduce debugging time, and provide valuable learning opportunities.

Essential Development Tools

STM32CubeMX
STM32CubeMX is a graphical tool that helps you configure your microcontroller quickly. You can set up peripherals, clock settings, and pin assignments using an intuitive interface. This tool generates initialization code, saving you time and effort during development.
Tip: Use STM32CubeMX to visualize your microcontroller's configuration and ensure compatibility with your project requirements.
STM32CubeIDE
STM32CubeIDE is an integrated development environment (IDE) tailored for STM32 microcontrollers. It combines code editing, debugging, and compiling in one platform. You can write your application code, test it, and debug errors without switching between tools.
Note: STM32CubeIDE supports multiple programming languages, including C and C++, making it versatile for different coding preferences.
Debugger Tools
Debugging tools like ST-Link and J-Link allow you to test your code directly on the microcontroller. These tools help you identify issues in real-time and optimize your application for better performance.
Tip: Invest in a reliable debugger to streamline your development process and reduce troubleshooting time.

Libraries and Middleware

Both microcontrollers benefit from STM32Cube firmware libraries. These libraries include pre-written code for common tasks, such as communication protocols (UART, SPI, I2C) and peripheral control. Middleware like FreeRTOS is also available, enabling you to implement multitasking in your application.

Resource	Purpose	Benefit
STM32Cube Libraries	Peripheral and protocol control	Saves development time
FreeRTOS	Real-time operating system	Enables multitasking and scheduling

Callout: Explore STM32Cube libraries to reduce coding complexity and focus on your application's unique features.

Community Support

The STM32 community is vast and active. You can find forums, tutorials, and example projects to guide you through challenges. Websites like STMicroelectronics' official forum and platforms like GitHub host valuable resources shared by developers worldwide.

Forums: Ask questions and get answers from experienced developers.
Tutorials: Learn step-by-step processes for configuring and programming your microcontroller.
Example Projects: Study real-world applications to understand best practices.

Emoji Tip: 💡 Join STM32 forums to connect with experts and gain insights into advanced techniques.

Open-Source Tools

You can also leverage open-source tools like PlatformIO for STM32 development. PlatformIO provides a lightweight IDE and supports multiple frameworks, making it ideal for cross-platform projects.

# Example of PlatformIO configuration for STM32G474RET6
[env:stm32g474ret6]
platform = ststm32
board = nucleo_g474re
framework = stm32cube

Tip: Open-source tools like PlatformIO offer flexibility and cost-effective solutions for hobbyists and professionals alike.

Documentation and Tutorials

STMicroelectronics provides detailed datasheets, reference manuals, and application notes for both microcontrollers. These documents explain hardware features, programming techniques, and best practices. Tutorials on platforms like YouTube and Coursera offer visual guidance for beginners.

Note: Always refer to the official documentation for accurate and up-to-date information about your microcontroller.

Why These Resources Matter

Development tools and community resources empower you to build reliable applications efficiently. They reduce the learning curve, help you troubleshoot issues, and ensure your project meets industry standards. By leveraging these resources, you can focus on innovation rather than reinventing the wheel.

Choosing between the STM32G474RET6 and STM32G474RCT6 depends on your project's specific needs. The STM32G474RET6 offers more flash memory and I/O pins, making it ideal for complex applications like motor control or real-time data processing. The STM32G474RCT6, with fewer features, suits simpler tasks and tighter budgets. Both microcontrollers share the same core architecture, ensuring reliable performance.

You should always align your microcontroller choice with your project's requirements. Consider factors like memory, connectivity, and cost to make an informed decision. This approach ensures your design remains efficient and cost-effective.

FAQ

1. What is the main difference between STM32G474RET6 and STM32G474RCT6?

The STM32G474RET6 has 512 KB of flash memory, while the STM32G474RCT6 offers 256 KB. If your project requires more storage for code or data, the STM32G474RET6 is the better choice. Both models share the same ARM Cortex-M4 processor for reliable performance.

2. Which microcontroller is better for cost-sensitive projects?

The STM32G474RCT6 is more affordable due to its smaller flash memory and fewer features. It’s ideal for simpler applications like basic sensor integration or control tasks. Choose this model if your project has budget constraints but doesn’t require advanced capabilities.

3. Can I use STM32G474RET6 for high-temperature environments?

Yes, the STM32G474RET6 operates within a temperature range of -40°C to 125°C. It’s suitable for industrial and outdoor applications, including automotive systems. This wide range ensures reliable performance in extreme conditions.

4. Are development tools available for both microcontrollers?

Both microcontrollers are supported by STM32CubeMX and STM32CubeIDE. These tools simplify configuration, code generation, and debugging. You can also access STM32Cube libraries and middleware like FreeRTOS to streamline development.

5. How do I decide which microcontroller to use?

Evaluate your project’s requirements. If you need more memory, I/O pins, or advanced peripherals, choose STM32G474RET6. For simpler tasks or tighter budgets, STM32G474RCT6 is a cost-effective option. Consider factors like application complexity, cost, and availability.

Specifications

STMicroelectronics STM32G474RET6 technical specifications, attributes, parameters and parts with similar specifications to STMicroelectronics STM32G474RET6.

Type
Parameter
Factory Lead Time
10 Weeks
Mounting Type
The "Mounting Type" in electronic components refers to the method used to attach or connect a component to a circuit board or other substrate, such as through-hole, surface-mount, or panel mount.
Surface Mount
Package / Case
refers to the protective housing that encases an electronic component, providing mechanical support, electrical connections, and thermal management.
64-LQFP
Surface Mount
having leads that are designed to be soldered on the side of a circuit board that the body of the component is mounted on.
YES
Data Converters
A/D 26x12b; D/A 7x12b
Number of I/Os
52
Operating Temperature
The operating temperature is the range of ambient temperature within which a power supply, or any other electrical equipment, operate in. This ranges from a minimum operating temperature, to a peak or maximum operating temperature, outside which, the power supply may fail.
-40°C~85°C TA
Packaging
Semiconductor package is a carrier / shell used to contain and cover one or more semiconductor components or integrated circuits. The material of the shell can be metal, plastic, glass or ceramic.
Tray
Series
In electronic components, the "Series" refers to a group of products that share similar characteristics, designs, or functionalities, often produced by the same manufacturer. These components within a series typically have common specifications but may vary in terms of voltage, power, or packaging to meet different application needs. The series name helps identify and differentiate between various product lines within a manufacturer's catalog.
STM32G4
Part Status
Parts can have many statuses as they progress through the configuration, analysis, review, and approval stages.
Active
Moisture Sensitivity Level (MSL)
Moisture Sensitivity Level (MSL) is a standardized rating that indicates the susceptibility of electronic components, particularly semiconductors, to moisture-induced damage during storage and the soldering process, defining the allowable exposure time to ambient conditions before they require special handling or baking to prevent failures
3 (168 Hours)
Number of Terminations
64
Terminal Position
In electronic components, the term "Terminal Position" refers to the physical location of the connection points on the component where external electrical connections can be made. These connection points, known as terminals, are typically used to attach wires, leads, or other components to the main body of the electronic component. The terminal position is important for ensuring proper connectivity and functionality of the component within a circuit. It is often specified in technical datasheets or component specifications to help designers and engineers understand how to properly integrate the component into their circuit designs.
QUAD
Terminal Form
Occurring at or forming the end of a series, succession, or the like; closing; concluding.
GULL WING
Supply Voltage
Supply voltage refers to the electrical potential difference provided to an electronic component or circuit. It is crucial for the proper operation of devices, as it powers their functions and determines performance characteristics. The supply voltage must be within specified limits to ensure reliability and prevent damage to components. Different electronic devices have specific supply voltage requirements, which can vary widely depending on their design and intended application.
3V
Terminal Pitch
The center distance from one pole to the next.
0.5mm
Reach Compliance Code
Reach Compliance Code refers to a designation indicating that electronic components meet the requirements set by the Registration, Evaluation, Authorization, and Restriction of Chemicals (REACH) regulation in the European Union. It signifies that the manufacturer has assessed and managed the chemical substances within the components to ensure safety and environmental protection. This code is vital for compliance with regulations aimed at minimizing risks associated with hazardous substances in electronic products.
compliant
Supply Voltage-Max (Vsup)
The parameter "Supply Voltage-Max (Vsup)" in electronic components refers to the maximum voltage that can be safely applied to the component without causing damage. It is an important specification to consider when designing or using electronic circuits to ensure the component operates within its safe operating limits. Exceeding the maximum supply voltage can lead to overheating, component failure, or even permanent damage. It is crucial to adhere to the specified maximum supply voltage to ensure the reliable and safe operation of the electronic component.
3.6V
Supply Voltage-Min (Vsup)
The parameter "Supply Voltage-Min (Vsup)" in electronic components refers to the minimum voltage level required for the component to operate within its specified performance range. This parameter indicates the lowest voltage that can be safely applied to the component without risking damage or malfunction. It is crucial to ensure that the supply voltage provided to the component meets or exceeds this minimum value to ensure proper functionality and reliability. Failure to adhere to the specified minimum supply voltage may result in erratic behavior, reduced performance, or even permanent damage to the component.
1.71V
Oscillator Type
Wien Bridge Oscillator; RC Phase Shift Oscillator; Hartley Oscillator; Voltage Controlled Oscillator; Colpitts Oscillator; Clapp Oscillators; Crystal Oscillators; Armstrong Oscillator.
Internal
Speed
In electronic components, "Speed" typically refers to the rate at which data can be processed or transferred within the component. It is a measure of how quickly the component can perform its functions, such as executing instructions or transmitting signals. Speed is often specified in terms of frequency, such as clock speed in processors or data transfer rate in memory modules. Higher speed components can perform tasks more quickly, leading to improved overall performance in electronic devices. It is an important parameter to consider when designing or selecting electronic components for specific applications.
170MHz
RAM Size
RAM size refers to the amount of random access memory (RAM) available in an electronic component, such as a computer or smartphone. RAM is a type of volatile memory that stores data and instructions that are actively being used by the device's processor. The RAM size is typically measured in gigabytes (GB) and determines how much data the device can store and access quickly for processing. A larger RAM size allows for smoother multitasking, faster loading times, and better overall performance of the electronic component. It is an important factor to consider when choosing a device, especially for tasks that require a lot of memory, such as gaming, video editing, or running multiple applications simultaneously.
128K x 8
Voltage - Supply (Vcc/Vdd)
Voltage - Supply (Vcc/Vdd) is a key parameter in electronic components that specifies the voltage level required for the proper operation of the device. It represents the power supply voltage that needs to be provided to the component for it to function correctly. This parameter is crucial as supplying the component with the correct voltage ensures that it operates within its specified limits and performance characteristics. It is typically expressed in volts (V) and is an essential consideration when designing and using electronic circuits to prevent damage and ensure reliable operation.
1.71V~3.6V
uPs/uCs/Peripheral ICs Type
The parameter "uPs/uCs/Peripheral ICs Type" refers to the classification of various integrated circuits used in electronic devices. It encompasses microprocessors (uPs), microcontrollers (uCs), and peripheral integrated circuits that provide additional functionalities. This classification helps in identifying the specific type of chip used for processing tasks, controlling hardware, or interfacing with other components in a system. Understanding this parameter is essential for selecting the appropriate electronic components for a given application.
MICROCONTROLLER, RISC
Core Processor
The term "Core Processor" typically refers to the central processing unit (CPU) of a computer or electronic device. It is the primary component responsible for executing instructions, performing calculations, and managing data within the system. The core processor is often considered the brain of the device, as it controls the overall operation and functionality. It is crucial for determining the speed and performance capabilities of the device, as well as its ability to handle various tasks and applications efficiently. In modern devices, core processors can have multiple cores, allowing for parallel processing and improved multitasking capabilities.
ARM® Cortex®-M4F
Peripherals
In the context of electronic components, "Peripherals" refer to devices or components that are connected to a main system or device to enhance its functionality or provide additional features. These peripherals can include input devices such as keyboards, mice, and touchscreens, as well as output devices like monitors, printers, and speakers. Other examples of peripherals include external storage devices, network adapters, and cameras. Essentially, peripherals are external devices that expand the capabilities of a main electronic system or device.
Brown-out Detect/Reset, DMA, I2S, POR, PWM, WDT
Clock Frequency
Clock frequency, also known as clock speed, refers to the rate at which a processor or electronic component can execute instructions. It is measured in hertz (Hz) and represents the number of cycles per second that the component can perform. A higher clock frequency typically indicates a faster processing speed and better performance. However, it is important to note that other factors such as architecture, efficiency, and workload also play a significant role in determining the overall performance of a component. In summary, clock frequency is a crucial parameter that influences the speed and efficiency of electronic components in processing data and executing tasks.
48MHz
Program Memory Type
Program memory typically refers to flash memory when it is used to hold the program (instructions). Program memory may also refer to a hard drive or solid state drive (SSD). Contrast with data memory.
FLASH
Core Size
Core size in electronic components refers to the physical dimensions of the core material used in devices such as inductors and transformers. The core size directly impacts the performance characteristics of the component, including its inductance, saturation current, and frequency response. A larger core size typically allows for higher power handling capabilities and lower core losses, while a smaller core size may result in a more compact design but with limitations on power handling and efficiency. Designers must carefully select the core size based on the specific requirements of the application to achieve optimal performance and efficiency.
32-Bit
Program Memory Size
Program Memory Size refers to the amount of memory available in an electronic component, such as a microcontroller or microprocessor, that is used to store program instructions. This memory is non-volatile, meaning that the data stored in it is retained even when the power is turned off. The program memory size determines the maximum amount of code that can be stored and executed by the electronic component. It is an important parameter to consider when selecting a component for a specific application, as insufficient program memory size may limit the functionality or performance of the device.
512KB 512K x 8
Connectivity
In electronic components, "Connectivity" refers to the ability of a component to establish and maintain connections with other components or devices within a circuit. It is a crucial parameter that determines how easily signals can be transmitted between different parts of a circuit. Connectivity can be influenced by factors such as the number of input and output ports, the type of connectors used, and the overall design of the component. Components with good connectivity are essential for ensuring reliable and efficient operation of electronic systems.
CANbus, I2C, IrDA, LINbus, QSPI, SPI, UART/USART
Bit Size
In electronic components, "Bit Size" refers to the number of bits that can be processed or stored by a particular component. A bit is the smallest unit of data in computing and can have a value of either 0 or 1. The Bit Size parameter is commonly used to describe the capacity or performance of components such as microprocessors, memory modules, and data buses. A larger Bit Size generally indicates a higher processing capability or storage capacity, allowing for more complex operations and larger amounts of data to be handled efficiently. It is an important specification to consider when selecting electronic components for specific applications that require certain levels of performance and data processing capabilities.
32
Has ADC
Has ADC refers to the presence of an Analog-to-Digital Converter (ADC) in an electronic component. An ADC is a crucial component in many electronic devices as it converts analog signals, such as voltage or current, into digital data that can be processed by a digital system. Having an ADC allows the electronic component to interface with analog signals and convert them into a format that can be manipulated and analyzed digitally. This parameter is important for applications where analog signals need to be converted into digital form for further processing or control.
YES
DMA Channels
DMA (Direct Memory Access) Channels are a feature found in electronic components such as microcontrollers, microprocessors, and peripheral devices. DMA Channels allow data to be transferred directly between peripherals and memory without involving the CPU, thereby reducing the burden on the CPU and improving overall system performance. Each DMA Channel is typically assigned to a specific peripheral device or memory region, enabling efficient data transfer operations. The number of DMA Channels available in a system determines the concurrent data transfer capabilities and can vary depending on the specific hardware design. Overall, DMA Channels play a crucial role in optimizing data transfer efficiency and system performance in electronic devices.
YES
PWM Channels
PWM Channels, or Pulse Width Modulation Channels, refer to the number of independent PWM outputs available in an electronic component, such as a microcontroller or a motor driver. PWM is a technique used to generate analog-like signals by varying the duty cycle of a square wave signal. Each PWM channel can control the output of a specific device or component by adjusting the pulse width of the signal. Having multiple PWM channels allows for precise control of multiple devices simultaneously, making it a valuable feature in applications such as motor control, LED dimming, and audio signal generation. The number of PWM channels available in a component determines the flexibility and complexity of the system it can control.
YES
Length
10mm
Width
10mm