#32 bit programmable microcontrollers | Explore Tumblr posts and blogs

techtease · 5 months ago

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UHF Reader Based on Pico W & ESP32 with 50 Tags/Second Reading within 1.5 Meter Range

A UHF Reader (Ultra High Frequency Reader) is a device that is used to read and write data from UHF RFID tags within the 860MHz-960MHz frequency range. It is a multi tags 50 tags/second reading/writing device within 1-1.5 meter range designed with cutting edge UHF technology. It is a compact, portable and easy to use device.

The UHF reader has 2 variants: one is UHF Reader by Pico W and another is UHF Reader by ESP32. The Pico W variant comes with RP2040 microcontroller with Wi-Fi and BLE support. It is compatible with MicroPython, CircuitPython and Arduino for programming. ESP32 variant comes with ESP32 S3 series microcontroller and has 2.4GHz & Bluetooth 5 (LE) support. It is compatible with Arduino and Espressif IDE for programming.

Key Features and Specifications:

UHF Reader Pico Variant:

RP2040 microcontroller dual-core Arm Cortex M0+ microprocessor with 264kB RAM

Supports Wi-Fi and BLE

1.14” TFT display for better visualization

Multi-tone buzzer for audio alerts

Micro USB Support for programming & Type C support for power

3 programmable buttons and Reset button

SD card slot for data storage/transfer

LED Status for power and battery charging

Multipurpose GPIOs breakout for interfacing external peripherals

SWD pins breakout for serial debugging

Supports MicroPython, CircuitPython, and Arduino for programming

UHF Reader ESP32 Variant:

Dual-core 32 bit LX7 microprocessor with Up to 8 MB PSRAM and up to 16 MB flash memory

Supports 2.4GHz (802.11b/g/n) Wi-Fi and Bluetooth 5 (LE)

1.14” TFT display with ST7789 display driver

Comes with a Read and Write UHF module.

Frequency range of 865.1MHz-867.9MHz (for EU/UK) and 902.25MHz-927.75MHz (for US)

Can Identify 50 tags/second up to the 1.5-meter range.

TTL UART communication interface and communication baud rates 115200bps-38400bps

output power 18-26dBm and output power accuracy +/- 1dB

operation current 180mA at 3.5V (26 dBm Output), 110mA at 3.5V (18 dBm Output)

Multi-tone buzzer for audio alerts

2 user programmable buttons, Boot and Reset buttons

For power and programming support, the Type C Interface

SD Card slot for data transfer/storage

LED status for power and charging

Multipurpose GPIOs breakout for interfacing external peripherals

Supports Arduino and Espressif IDE for programming

By using ESP32 and RP2040, you can build a UHF RFID reader for scan tags and data tracking. This UHF Reader with ESP32 and Pico by SB Components is suitable for applications like warehouses, retail stores, and many other applications where you want to track your inventory data accurately.

#technology #innovation #tech #iot #rfid #uhf #uhf reader #arduino #espressif #iot applications #raspberry pi #rp2040 #esp32 #projects #programming #ultra high frequency reader #rfid tags #data tracking #electronics

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ovaga-technologies · 9 months ago

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STM32F103C6T6 Datasheet, Pinout, and Specifications

The STM32F103C6T6 is a powerful microcontroller known for its versatility and performance. It belongs to the STM32F1 series produced by STMicroelectronics, offering a wide range of features and capabilities. This microcontroller is highly regarded in the world of embedded systems and microcontroller applications due to its robustness, cost-effectiveness, and ease of use. Its popularity stems from its ability to cater to a wide range of applications, from simple DIY projects to complex industrial automation systems. In this article, we'll provide an overview of theSTM32F103C6T6, exploring its specifications, schematic, pinout, programming, datasheet, and more details.

Description of STM32F103C6T6

The STM32F103C6T6 performance line family integrates the high-performance ARM Cortex-M3 32-bit RISC core, operating at a frequency of 72 MHz. It features high-speed embedded memories (Flash memory up to 32 Kbytes and SRAM up to 6 Kbytes) and a wide range of enhanced I/Os and peripherals connected to two APB buses. All devices offer two 12-bit ADCs, three general-purpose 16-bit timers plus one PWM timer, as well as standard and advanced communication interfaces: up to two I2Cs and SPIs, three USARTs, a USB, and a CAN.

The STM32F103C6T6 low-density performance line family operates from a 2.0 to 3.6 V power supply. It is available in both the –40 to +85 °C temperature range and the –40 to +105 °C extended temperature range. A comprehensive set of power-saving modes allows for the design of low-power applications.

The STM32F103C6T6 low-density performance line family includes devices in four different package types, ranging from 36 pins to 64 pins. Depending on the chosen device, different sets of peripherals are included. The following description provides an overview of the complete range of peripherals proposed in this family.

These features make the STM32F103C6T6 low-density performance line microcontroller family suitable for a wide range of applications such as motor drives, application control, medical and handheld equipment, PC and gaming peripherals, GPS platforms, industrial applications, PLCs, inverters, printers, scanners, alarm systems, video intercoms, and HVACs.

Features of STM32F103C6T6

ARM 32-bit Cortex™-M3 CPU Core: The microcontroller is powered by an ARM Cortex™-M3 CPU core, capable of operating at a maximum frequency of 72 MHz. It delivers a performance of 1.25 DMIPS/MHz (Dhrystone 2.1) with 0 wait state memory access and supports single-cycle multiplication and hardware division.

Versatile Memories: The STM32F103C6T6 features 16 or 32 Kbytes of Flash memory for program storage and 6 or 10 Kbytes of SRAM for data storage.

Clock, Reset, and Supply Management: It supports 2.0 to 3.6 V application supply and I/Os. The microcontroller includes a Power-On Reset (POR), a Power-Down Reset (PDR), and a programmable voltage detector (PVD). It also features a 4-to-16 MHz crystal oscillator, an internal 8 MHz factory-trimmed RC oscillator, and an internal 40 kHz RC oscillator. Additionally, it provides a PLL for the CPU clock and a 32 kHz oscillator for the Real-Time Clock (RTC) with calibration.

Low Power: The STM32F103C6T6 offers Sleep, Stop, and Standby modes for power optimization. It includes VBAT supply for RTC and backup registers.

2 x 12-bit, 1 µs A/D Converters: The microcontroller is equipped with two 12-bit analog-to-digital converters (ADC) with up to 16 channels. It has a conversion range of 0 to 3.6 V and supports dual-sample and hold capability. Additionally, it features a temperature sensor.

Direct Memory Access (DMA): It includes a 7-channel DMA controller that supports peripherals such as timers, ADC, SPIs, I2Cs, and USARTs.

Up to 51 Fast I/O Ports: The STM32F103C6T6 offers 26/37/51 I/Os, all mappable on 16 external interrupt vectors. Almost all ports are 5 V-tolerant, providing flexibility in interfacing with various external devices.

STM32F103C6T6 Specifications

TypeParameterCoreARM Cortex M3

Core Size

32-Bit Single-CoreProgram Memory Size32 kBData Bus Width32 bitADC Resolution12 bitMaximum Clock Frequency72 MHzRAM Size10K x 8Supply Voltage - Min1.8 V, 2 VSupply Voltage - Max3.6 VVoltage - Supply (Vcc/Vdd)2V ~ 3.6VConnectivityCANbus, I2C, IrDA, LINbus, SPI, UART/USART, USBPeripheralsDMA, Motor Control PWM, PDR, POR, PVD, PWM, Temp Sensor, WDTNumber of I/Os48 I/O

Operating Temperature

-40°C ~ 85°C (TA)

Package / Case

48-LQFP

Absolute Maximum Ratings

SymbolRatingsValueVDD − VSSExternal main supply voltage (including VDDA and VDD)–0.3V ~ 4.0VVINInput voltage on five volt tolerant pinVSS − 0.3V ~ VDD + 4.0VInput voltage on any other pinVSS − 0.3V ~ 4.0V|VDDx|Variations between different VDD power pins50mV|VSSX −VSS|Variations between all the different ground pins50mVVESD(HBM)Electrostatic discharge voltage (human body model)2000VIVDDTotal current into VDD/VDDA power lines (source)150mAIVSSTotal current out of VSS ground lines (sink)150mAIIOOutput current sunk by any I/O and control pin 25mAOutput current source by any I/Os and control pin-25mAIINJ(PIN)Injected current on five volt tolerant pins-5/+0mAInjected current on any other pin± 5mAΣIINJ(PIN)Total injected current (sum of all I/O and control pins)± 25mATSTGStorage temperature range–65°C to +150°CTJMaximum junction temperature150°C

STM32F103C6T6 Pinout

STM32F103C6T6 Application

Motor Drives

The STM32F103C6T6 is used in motor drive systems to control the speed and direction of motors in various applications, such as industrial machinery, robotics, and automotive systems.

Application Control

It is utilized for controlling the operation of various applications, including home automation systems, smart appliances, and industrial automation equipment.

Medical and Handheld Equipment

Due to its low power consumption and high processing capabilities, the microcontroller is employed in medical devices such as portable monitoring systems, infusion pumps, and handheld diagnostic tools.

PC and Gaming Peripherals

STM32F103C6T6 is used in peripherals for PCs and gaming consoles, such as keyboards, mice, and game controllers, to provide efficient and reliable control interfaces.

GPS Platforms

It is used in GPS tracking devices and navigation systems to process location data and provide accurate positioning information.

Industrial Applications

Due to its robustness and reliability, the microcontroller is widely used in various industrial applications, including factory automation, process control, and monitoring systems.

PLCs (Programmable Logic Controllers)

It is utilized in PLCs for controlling and monitoring industrial processes and machinery.

Inverters

STM32F103C6T6 is used in power inverters, which convert DC power to AC power in applications such as solar power systems and uninterruptible power supplies (UPS).

Printers and Scanners

It is used in printers and scanners for controlling printing and scanning functions, providing fast and efficient operations.

Alarm Systems

The microcontroller is used in alarm systems for detecting and signaling unauthorized entry or other security breaches.

Video Intercoms

It is used in video intercom systems for communication and remote access control in residential and commercial buildings.

HVAC (Heating, Ventilation, and Air Conditioning)

STM32F103C6T6 is used in HVAC systems for controlling temperature, humidity, and air quality, ensuring comfortable and energy-efficient indoor environments.

STM32F103C6T6 Programming

To program the STM32F103C6T6, developers can use a variety of development tools and integrated development environments (IDEs) such as Keil, STM32CubeIDE, and Arduino IDE. These tools provide a user-friendly interface for writing, compiling, and debugging code for the microcontroller.

IDEs for STM32F103C6T6

Several integrated Development Environments (IDEs) support STM32F103C6T6, including the STM32CubeIDE, Keil uVision, and CoIDE. Each offers a unique set of features, catering to different programming needs and preferences.

STM32CubeIDE

STM32CubeIDE is an official IDE from STMicroelectronics for STM32 development. It integrates the STM32Cube library, providing a comprehensive software infrastructure to streamline the programming process.

Keil uVision

Keil uVision is another popular choice. It offers robust debugging capabilities, making it easier for developers to identify and resolve errors in their code.

STM32CubeMX is a graphical tool that helps developers configure the microcontroller and generate initialization code quickly. It allows users to configure peripherals, pin assignments, and clock settings, among other parameters. Then, it generates the corresponding initialization code in C language, which can be easily integrated into the development environment.

Another essential aspect of programming the STM32F103C6T6 is understanding the HAL (Hardware Abstraction Layer) libraries provided by STMicroelectronics. HAL libraries abstract the low-level hardware details, providing a standardized interface for interacting with the microcontroller's peripherals. This abstraction simplifies the development process and makes the code more portable across different STM32 microcontrollers. Understanding how to use HAL libraries is essential for efficiently programming the STM32F103C6T6 and leveraging its full potential in embedded applications.

STM32F103C6T6 Equivalent/Alternative

STM32F103C8T6.

STM32F103C6T6 Package

STM32F103C6T6 Manufacturer

STMicroelectronics, a global leader in semiconductor manufacturing, is the proud manufacturer of the STM32F103C6T6 microcontroller. With a strong focus on innovation and quality, STMicroelectronics has established itself as a trusted name in the electronics industry. The company's commitment to excellence is evident in the STM32F103C6T6, which boasts high performance, reliability, and versatility. STMicroelectronics' dedication to customer satisfaction and technological advancement makes it a preferred choice for engineers and designers worldwide.

STM32F103C6T6 Datasheet

Download STM32F103C6T6 Datasheet PDF.

Conclusion

In conclusion, the STM32F103C6T6 microcontroller stands out as a versatile and powerful solution for embedded systems design. Its advanced features, including a 32-bit ARM Cortex-M3 core, a wide range of peripherals, and low power consumption, make it ideal for a variety of applications. It provides developers with a powerful tool to create innovative and efficient solutions for a wide range of applications.

#STM32F103C6T6

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ainow · 10 months ago

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Buy ST-Link V2 Programmer at Affordable Price in Ainow

ST-Link V2 Programmer For STM8 and STM32 is fully consistent with the official version, support for automatic upgrades, support the full range STM32 SWD (only 4pins including SWCLK, SWDIO, and power) and a full range STM8 SWIM (only 4pins including SWIM, Reset and power) download and debug. Use this device to send program code to the 32-bit STM32 ARM Cortex or 8-bit STM8 microcontrollers. The header for this ST-Link v2 programmer contains connections for 5V, 3.3V, SWCLK, SWDIO, SWIM, Reset (RST/NRST) and GND. The connector on the opposite side of this device is a USB connector and is intended to be plugged into the computer.

Note: The product is available in Multiple colors Will be shipped randomly.

Supports For ST-LINK V2 Programmer:

ST-LINK Utility 2.0 and above.

STVD 4.2.1 and above.

STVP 3.2.3 and above.

IAR EWARM V6.20 and above.

IAR EWSTM8 V1.30 and above.

KEIL RVMDK V4.21 and above.

Features :

PCB installed inside of aluminum alloy U disk shell, portable, safe and reliable!

Interface definition directly marked on the shell, clear, convenient and practical!

5V, 3.3V offers at the same time, allowing you to program your target board with both 5V and 3.3V

Shell characters using laser engraving, never fade off! Permanent clarity!

500MA internal resettable fuse, complete protection of your expensive computer motherboard!

Red and blue color LED indicator, allowing you to always observe ST-LINK V2 working condition!

With 4 DuPont line, so you can easily respond to different target board line order!

Use anti-static bag packaging.

SWIM specific features:

SWIM cable for connection to the application via a pin header or a 2.54 mm pitch connector

1.65 V to 5.5 V application voltage supported on SWIM interface

SWIM low-speed and high-speed modes supported

SWIM programming speed rate: 9.7 Kbytes/s in low speed and 12.8 Kbytes/s in high speed

SWIM cable for connection to the application

Direct firmware update feature supported (DFU)

Status LED which blinks during communication with the PC

Operating temperature 0 to 50Â°C

#electronic components #sales in chennai #arduino #sensor #raspberrypi

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martech360 · 10 months ago

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Semiconductor Chips Explained: Different Types and Their Uses

In today’s fast-paced technological landscape, there is a growing demand for faster and more efficient devices. This need, however, brings a significant challenge: balancing cost and energy consumption while enhancing the performance and functionality of electronic gadgets.

Introduction to Semiconductor Chips

Semiconductor chips are crucial in this regard. The global semiconductor market is projected to reach $687 billion by 2025, showcasing the transformative impact of these chips across various sectors, from computers and smartphones to advanced AI systems and IoT devices. Let's delve deeper into this billion-dollar industry.

What Is A Semiconductor Chip?

A semiconductor chip, also known as an integrated circuit or computer chip, is a small electronic device made from semiconductor materials like silicon. It contains millions or even billions of transistors, which are tiny electronic components capable of processing and storing data.

These chips are the backbone of modern technology, found in a vast array of electronic devices including computers, smartphones, cars, and medical equipment. Manufacturing semiconductor chips involves a complex, multi-step process that includes slicing silicon wafers, printing intricate circuit designs, and adding multiple layers of components and interconnects. Leading companies in the semiconductor industry include Samsung, TSMC, Qualcomm, Marvell, and Intel.

Types of Semiconductor Chips

Memory Chips

Function: Store data and programs in computers and other devices.

Types:

RAM (Random-Access Memory): Provides temporary workspaces.

Flash Memory: Stores information permanently.

ROM (Read-Only Memory) and PROM (Programmable Read-Only Memory): Non-volatile memory.

EPROM (Erasable Programmable Read-Only Memory) and EEPROM (Electrically Erasable Programmable Read-Only Memory): Can be reprogrammed.

Microprocessors

Function: Contain CPUs that power servers, PCs, tablets, and smartphones.

Architectures:

32-bit and 64-bit: Used in PCs and servers.

ARM: Common in mobile devices.

Microcontrollers (8-bit, 16-bit, and 24-bit): Found in toys and vehicles.

Graphics Processing Units (GPUs)

Function: Render graphics for electronic displays, enhancing computer performance by offloading graphics tasks from the CPU.

Applications: Modern video games, cryptocurrency mining.

Commodity Integrated Circuits (CICs)

Function: Perform repetitive tasks in devices like barcode scanners.

Types:

ASICs (Application-Specific Integrated Circuits): Custom-designed for specific tasks.

FPGAs (Field-Programmable Gate Arrays): Customizable after manufacturing.

SoCs (Systems on a Chip): Integrate all components into a single chip, used in smartphones.

Analog Chips

Function: Handle continuously varying signals, used in power supplies and sensors.

Components: Include transistors, inductors, capacitors, and resistors.

Mixed-Circuit Semiconductors

Function: Combine digital and analog technologies, used in devices requiring both types of signals.

Examples: Microcontrollers with ADCs (Analog-to-Digital Converters) and DACs (Digital-to-Analog Converters).

Manufacturing Process of Semiconductor Chips

Semiconductor device fabrication involves several steps to create electronic circuits on a silicon wafer. Here’s an overview:

Wafer Preparation: Silicon ingots are shaped and sliced into thin wafers.

Cleaning and Oxidation: Wafers are cleaned and oxidized to form a silicon dioxide layer.

Photolithography: Circuit patterns are transferred onto wafers using UV light and photoresist.

Etching: Unwanted material is removed based on the photoresist pattern.

Doping: Ions are implanted to alter electrical properties.

Deposition: Thin films of materials are deposited using CVD or PVD techniques.

Annealing: Wafers are heated to activate dopants and repair damage.

Testing and Packaging: Finished wafers are tested, diced into individual chips, and packaged for protection.

Conclusion

Semiconductor chips are fundamental to the functionality of nearly every electronic device we use today. They have revolutionized technology by enabling faster, smaller, and more powerful devices. While the semiconductor industry has fueled job creation and economic growth, it also faces challenges related to sustainability and environmental impact. As we continue to push the boundaries of innovation, ethical practices are essential to ensure semiconductors remain vital to our modern world and shape our future.

#semiconductors #electronic #analogchip

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