Two separate simulated circuits which demonstrate how step up and step down type transformers work.

Programmable USB Type‐C Controller with Power Delivery(PD) support. Include ESD Protection Diodes. #project-template #USB #typec #powerdelivery #template

Programmable USB Type‐C Controller with Power Delivery(PD) support. Include ESD Protection Diodes. #project-template #USB #typec #powerdelivery #template

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

Two separate simulated circuits which demonstrate how step up and step down transformers work.

This project is a plant care system that uses an ESP32-S3-MINI-1U-N8 microcontroller to automate plant care tasks. This system includes three Songle relays, multiple resistors, capacitors, and transistors, all powered at 3.3V, 5V, or 12V. It also incorporates a USB Type-C connector. #referenceDesign #edge-computing #edgeComputing #espressif #template #iot #ESP32 #relay #reference-design

This is a WiFi to Infrared (IR) gateway reference design leveraging an ESP32-S3 microcontroller for WiFi connectivity. It also incorporates a Type-C USB interface for data and power, 3 LEDs (red, green, & IR), and voltage regulation. It facilitates wireless control of IR devices, suitable for home automation projects. #referenceDesign #edge-computing #espressif #template #IR #project #reference-design

FLORA has a small but easy to use onboard reset button to reboot the system. The power supply is designed to be flexible and easy to use. There is an onboard polarized 2 JST battery connector with protection schottky diode for use with external battery packs from 3.5v to 16v DC in. Can be used with LiIon/LiPoly, LiFe, alkaline or rechargeable NiMh/NiCad batteries of any size. The FLORA does not have a LiPo charger included by design, this allows safe use with multiple battery types and reduces risk of fire as it is not recommended to charge these batteries on fabric.

16 channel relay that will allow you to control different types of electrical loads

This project is a plant care system that uses an ESP32-S3-MINI-1U-N8 microcontroller to automate plant care tasks. This system includes three Songle relays, multiple resistors, capacitors, and transistors, all powered at 3.3V, 5V, or 12V. It also incorporates a USB Type-C connector. #referenceDesign #edge-computing #edgeComputing #espressif #template #iot #ESP32 #relay #reference-design

This is a climate control system reference design with a STM32WB5 microcontroller, power manager IC, USB Type-C, JST connectors, and an LCD driver. #referenceDesign #edge-computing #edgeComputing #stm #template #iot #control #BLE #reference-design

Learn how to use Copilot, your AI design assistant, to brainstorm and develop a new idea from concept to custom board design. Discuss requirements, generate architectures, research parts, and draw your schematic.

CT Scanner DAS board design based on DDC232 ADC, iCE40 UltraPlus FPGA, and STM32F745 MCU integration. Designed for efficient data acquisition and processing #scanner #ice40 #computedTomography #STM32F745

CT Scanner DAS board design based on DDC232 ADC, iCE40 UltraPlus FPGA, and STM32F745 MCU integration. Designed for efficient data acquisition and processing #scanner #ice40 #computedTomography #STM32F745

Welcome to your new project. Imagine what you can build here.

A circuit for a gps tracker using stm32f103c8t6 and sim 808, that acquires and sends gps coordinates to a separate interfaced application. The circuit will be powered by a 12v dc battery so there a need for power regulation. there is a USB type micro B for code uploading.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Product Type: Wearable AI pendant Primary Function: Records audio, generates transcripts, and organizes information about daily interactions User Interaction: Input: Activation button Output: RGB LED ring, Bluetooth link to phone Key Features: Audio Recording: Activated by button press Transcription: Converts audio to text Sentiment Analysis: Embedded AI evaluates sentiment Information Management: Filters essential information and action items Technical Specifications Form Factor: Wearable pendant Display: RGB LED ring around the edge Sensors: 2 Microphones 1 Button Connectivity: Bluetooth for phone linkage Wi-Fi USB-C for charging Wireless Protocol: Wi-Fi, Bluetooth Battery Type: LiPo 2000 mAh Battery Life: 6 hours of continuous use Charging Method: USB-C Operating Voltage: 3.3V Operating Conditions: Temperature Range: -10°C to 70°C Humidity: 10 to 90% Software: Python for AI and processing Compliance: RoHS, FCC, CE Reliability: 20,000 hrs Life Cycle Expectancy: 10 years AI Capabilities Speech to Text Recognition: Converts audio input to written text Embedded AI Sentiment Analysis: Evaluates the mood or sentiment expressed in the text Essential Information Filtering: Identifies and segregates crucial data and actionable items Power Consumption and Efficiency Power consumption must align with battery capacity to ensure 6 hours of continuous operational use.

Step-down type -40℃~+125℃@(TJ) 1 Step-down Adjustable 0.768V~7V 3A 4.5V~17V 580kHz SOT-23-6 DC-DC Converters ROHS #RegulatorSwitching #commonpartslibrary

Product Type: Wearable AI pendant Primary Function: Records audio, generates transcripts, and organizes information about daily interactions User Interaction: Input: Activation button Output: RGB LED ring, Bluetooth link to phone Key Features: Audio Recording: Activated by button press Transcription: Converts audio to text Sentiment Analysis: Embedded AI evaluates sentiment Information Management: Filters essential information and action items Technical Specifications Form Factor: Wearable pendant Display: RGB LED ring around the edge Sensors: 2 Microphones 1 Button Connectivity: Bluetooth for phone linkage Wi-Fi USB-C for charging Wireless Protocol: Wi-Fi, Bluetooth Battery Type: LiPo 2000 mAh Battery Life: 6 hours of continuous use Charging Method: USB-C Operating Voltage: 3.3V Operating Conditions: Temperature Range: -10°C to 70°C Humidity: 10 to 90% Software: Python for AI and processing Compliance: RoHS, FCC, CE Reliability: 20,000 hrs Life Cycle Expectancy: 10 years AI Capabilities Speech to Text Recognition: Converts audio input to written text Embedded AI Sentiment Analysis: Evaluates the mood or sentiment expressed in the text Essential Information Filtering: Identifies and segregates crucial data and actionable items Power Consumption and Efficiency Power consumption must align with battery capacity to ensure 6 hours of continuous operational use.

555 Type, Timer/Oscillator (Single) IC 1Mhz 8-PDIP

Two separate simulated circuits which demonstrate how step up and step down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step up and step down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step up and step down type transformers work.

Two separate simulated circuits which demonstrate how step up and step down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step up and step down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step up and step down type transformers work.

Two separate simulated circuits which demonstrate how step-up and step-down type transformers work.

Two separate simulated circuits which demonstrate how step up and step down type transformers work.