IoT Home Automation - DHT11(T/H) - Air Quality Monitoring ESP32 & Blynk ...

IoT Home Automation | Temperature, Humidity & Air Quality Monitoring using ESP32 & Blynk 2.0 | IoT Home Automation - DHT11(T/H) - Air Quality Monitoring ESP32 & Blynk App Notification📱Email Alert | How to Monitor Air Quality | Air Quality Monitoring System | ESP8266 | Blynk IOT Projects | Control System using ESP32 & Blynk 2.0 | Home Automation using ESP32 & Blynk 2.0 - IoT Projects Ideas | IoT based Air quality Monitoring system | Air pollution monitoring using MQ135 & ESP32 | IoT | esp32 | Home Automation using ESP32 & Blynk 2.0 - IoT Projects Ideas | Temperature, Humidity & Air Quality Monitoring. *********************************************************** If You Want To Purchase the Full Working Project KIT Mail Us: svsembedded@gmail.com Title Name Along With You-Tube Video Link We are Located at Telangana, Hyderabad, Boduppal. Project Changes also Made according to Student Requirements http://svsembedded.com/  https://www.svskits.in/ http://svsembedded.in/  http://www.svskit.com/ M1: +91 9491535690  M2: +91 7842358459 We Will Send Working Model Project KIT through DTDC / DHL / Blue Dart / First Flight Courier Service We Will Provide Project Soft Data through Google Drive 1. Project Abstract / Synopsis 2. Project Related Datasheets of Each Component 3. Project Sample Report / Documentation 4. Project Kit Circuit / Schematic Diagram 5. Project Kit Working Software Code 6. Project Related Software Compilers 7. Project Related Sample PPT’s 8. Project Kit Photos 9. Project Kit Working Video links Latest Projects with Year Wise YouTube video Links 157 Projects  https://svsembedded.com/ieee_2022.php 135 Projects  https://svsembedded.com/ieee_2021.php 151 Projects  https://svsembedded.com/ieee_2020.php 103 Projects  https://svsembedded.com/ieee_2019.php 61 Projects  https://svsembedded.com/ieee_2018.php 171 Projects  https://svsembedded.com/ieee_2017.php 170 Projects  https://svsembedded.com/ieee_2016.php 67 Projects  https://svsembedded.com/ieee_2015.php 55 Projects  https://svsembedded.com/ieee_2014.php 43 Projects  https://svsembedded.com/ieee_2013.php 1100+ Projects https://www.svskit.com/2022/02/900-pr... *********************************************************** It looks like you're interested in setting up an IoT home automation system using the DHT11 sensor to monitor temperature and humidity, an ESP32 microcontroller, and the Blynk app for notifications and email alerts. This is a great project idea! Here's a step-by-step guide to help you get started: Components Needed: 1. ESP32 development board. 2. DHT11 sensor (for temperature and humidity measurement). 3. Breadboard and jumper wires. 4. USB cable for power and programming. 5. Blynk app (downloadable from app stores). Steps: 1. Set Up the Hardware: • Connect the DHT11 sensor to the ESP32 using jumper wires. • Connect the VCC pin of the DHT11 to the 3.3V pin on the ESP32. • Connect the GND pin of the DHT11 to the GND pin on the ESP32. • Connect the DATA pin of the DHT11 to a GPIO pin on the ESP32 (e.g., GPIO 2). 2. Install Arduino IDE and ESP32 Board Support: • Download and install the Arduino IDE from the official website. • Open the Arduino IDE and go to "File" "Preferences". • Add the following URL to the "Additional Boards Manager URLs": https://dl.espressif.com/dl/package_e... • Go to "Tools" "Board" "Boards Manager", search for "esp32", and install the ESP32 board support. 3. Install Required Libraries: • In the Arduino IDE, go to "Sketch" "Include Library" "Manage Libraries". • Search and install the following libraries: • "DHT sensor library" by Adafruit. • "Blynk" by Blynk Inc. 4. Create a Blynk Account and Get Auth Token: • Download the Blynk app on your smartphone and create an account. • Create a new Blynk project and obtain the authentication token from the email sent to you. 6. Air Quality Monitoring: • You can add an additional sensor (e.g., MQ-135) to measure air quality. Connect it to the ESP32 and update the code accordingly. 7. Email Alert Configuration: • Blynk provides an email notification widget that you can add to your project. • Configure the widget to send an email when a specific condition (e.g., high temperature or humidity) is met. 8. Upload the Code: • Connect your ESP32 to your computer via USB. • Select the correct board and port in the Arduino IDE. • Click the "Upload" button to upload the code to your ESP32. 9. Monitor the Data: • Open the Serial Monitor in the Arduino IDE to view the data being read from the DHT11 sensor. 10. Monitor Data on Blynk App: • Open your Blynk app and check if the temperature and humidity values are being updated on the Value Display widgets. • Set up email alerts based on your chosen conditions.

GPS Clock Using Raspberry Pi Pico (RP2040) Arm Cortex-M0+ & LCD Display

GPS Clock Using Raspberry Pi Pico (RP2040) Arm Cortex-M0+ & LCD Display | Make a GPS Clock With Arduino - Projects | Arduino GPS Clock | raspberry pi | raspberry pi pico | raspberry pi real time clock | raspberry pi pico w | raspberry | raspberry pi pico gps | raspberry pi pico oled | raspberry pi pico gps tracker | raspberry pi 4 | raspberry pico | real time clock raspberry pi pico | raspberry pi pico real time clock | real time clock | raspberry pi pico nmea | real time clock raspberry pi | raspberry pi pico thonny | thonny raspberry pi pico | raspberry pi microcontroller | raspberry pi pico tutorial | raspberry pi zero. *********************************************************** If You Want To Purchase the Full Working Project KIT Mail Us: svsembedded@gmail.com Title Name Along With You-Tube Video Link We are Located at Telangana, Hyderabad, Boduppal. Project Changes also Made according to Student Requirements http://svsembedded.com/  https://www.svskits.in/ http://svsembedded.in/  http://www.svskit.com/ M1: +91 9491535690  M2: +91 7842358459 We Will Send Working Model Project KIT through DTDC / DHL / Blue Dart / First Flight Courier Service We Will Provide Project Soft Data through Google Drive 1. Project Abstract / Synopsis 2. Project Related Datasheets of Each Component 3. Project Sample Report / Documentation 4. Project Kit Circuit / Schematic Diagram 5. Project Kit Working Software Code 6. Project Related Software Compilers 7. Project Related Sample PPT’s 8. Project Kit Photos 9. Project Kit Working Video links Latest Projects with Year Wise YouTube video Links 157 Projects  https://svsembedded.com/ieee_2022.php 135 Projects  https://svsembedded.com/ieee_2021.php 151 Projects  https://svsembedded.com/ieee_2020.php 103 Projects  https://svsembedded.com/ieee_2019.php 61 Projects  https://svsembedded.com/ieee_2018.php 171 Projects  https://svsembedded.com/ieee_2017.php 170 Projects  https://svsembedded.com/ieee_2016.php 67 Projects  https://svsembedded.com/ieee_2015.php 55 Projects  https://svsembedded.com/ieee_2014.php 43 Projects  https://svsembedded.com/ieee_2013.php 1100+ Projects https://www.svskit.com/2022/02/900-pr... *********************************************************** Creating a GPS clock using a Raspberry Pi Pico (RP2040) with an Arm Cortex-M0+ processor and an LCD display is a fun and educational project. In this project, we will use the Pico's GPIO pins to communicate with a GPS module and an LCD display. The GPS module will provide the time and date information, and the LCD will display the clock. Here's a step-by-step guide to building the GPS clock: Components Required: 1. Raspberry Pi Pico (RP2040) 2. GPS module (e.g., NEO-6M or similar) 3. LCD display (e.g., 16x2 or 20x4) 4. Breadboard and jumper wires 5. Power supply for the Raspberry Pi Pico Step 1: Setting up the Hardware 1. Connect the GPS module to the Raspberry Pi Pico using jumper wires. Typically, the GPS module communicates over UART, so connect the TX pin of the GPS module to the RX pin (GPIO1) of the Pico and vice versa. Also, connect the GND and VCC (usually 3.3V) pins between the devices. 2. Connect the LCD display to the Raspberry Pi Pico using jumper wires. You will need at least six GPIO pins to control the LCD: RS, E, D4, D5, D6, and D7. Step 2: Setting up the Software 1. Install the latest version of Circuit Python on the Raspberry Pi Pico. You can find instructions on how to do this on the official Raspberry Pi Pico website. 2. Once Circuit Python is installed, you will see the Pico as a USB drive when connected to your computer. Create a new Python file (e.g., gps_clock.py) on the Pico and edit it using a text editor. 3. Install the necessary libraries for the GPS module and the LCD display. You can use the Adafruit Circuit Python GPS library for the GPS module and the Adafruit Circuit Python Char LCD library for the LCD display. Download the libraries and copy them to the lib folder on your Pico. Step 3: Writing the Code Now, let's write the Python code for the GPS clock. The code will read the time information from the GPS module and display it on the LCD. Step 4: Running the GPS Clock 1. Save the Python code on the Raspberry Pi Pico as gps_clock.py. 2. Safely eject the Pico from your computer and connect it to a power supply. 3. The GPS clock should now be up and running. The LCD will display the current time and date as received from the GPS module. Please note that the GPS module requires a clear view of the sky to get a fix on the GPS satellites. It may take a few minutes for the module to acquire its first fix. Once it has a fix, it should update the time and date regularly. Always ensure that you have a stable power supply for the Raspberry Pi Pico and any connected components to avoid unexpected behaviour or damage to the devices.

Vehicle Security System using Embedded and GSM Technology

Vehicle Security System using Embedded and GSM Technology | MICROCONTROLLER BASED VEHICLE ANTI-THEFT AND SECURITY SYSTEM | vehicle security system using 8051 microcontroller | vehicle tracking system using gps and arduino | using | vehicle | system | vehicle security system using arduino and sensors | accident detection and alert system using arduino | gsm based vehicle security system | gps based vehicle tracking system using arduino | vehicle security system using gsm | advance vehicle security system using arduino | vehicle security system using raspberry pi | security system using gps and gsm. *********************************************************** If You Want To Purchase the Full Working Project KIT Mail Us: svsembedded@gmail.com Title Name Along With You-Tube Video Link We are Located at Telangana, Hyderabad, Boduppal. Project Changes also Made according to Student Requirements http://svsembedded.com/  https://www.svskits.in/ http://svsembedded.in/  http://www.svskit.com/ M1: +91 9491535690  M2: +91 7842358459 We Will Send Working Model Project KIT through DTDC / DHL / Blue Dart / First Flight Courier Service We Will Provide Project Soft Data through Google Drive 1. Project Abstract / Synopsis 2. Project Related Datasheets of Each Component 3. Project Sample Report / Documentation 4. Project Kit Circuit / Schematic Diagram 5. Project Kit Working Software Code 6. Project Related Software Compilers 7. Project Related Sample PPT’s 8. Project Kit Photos 9. Project Kit Working Video links Latest Projects with Year Wise YouTube video Links 157 Projects  https://svsembedded.com/ieee_2022.php 135 Projects  https://svsembedded.com/ieee_2021.php 151 Projects  https://svsembedded.com/ieee_2020.php 103 Projects  https://svsembedded.com/ieee_2019.php 61 Projects  https://svsembedded.com/ieee_2018.php 171 Projects  https://svsembedded.com/ieee_2017.php 170 Projects  https://svsembedded.com/ieee_2016.php 67 Projects  https://svsembedded.com/ieee_2015.php 55 Projects  https://svsembedded.com/ieee_2014.php 43 Projects  https://svsembedded.com/ieee_2013.php 1100+ Projects https://www.svskit.com/2022/02/900-pr... *********************************************************** Creating a Vehicle Security System using Embedded and GSM Technology with the 8051 microcontroller requires careful planning and understanding of both hardware and software aspects. Here's a basic outline of how you can approach building such a system using the 8051 microcontroller: 1. Hardware Components: • 8051 Microcontroller: Choose a suitable 8051 microcontroller variant that meets your project requirements. • GSM Module: Select a GSM module that is compatible with the 8051 microcontroller and supports the necessary communication protocols (e.g., AT commands). • GPS Module (optional): If you want real-time location tracking, integrate a GPS module that communicates with the microcontroller via UART. • Sensors: Include various sensors like motion sensors, door sensors, shock sensors, and tilt sensors to detect unauthorized access or movement of the vehicle. • Alarm: Use a buzzer or a loudspeaker to create an audible alarm when suspicious activity is detected. • Relays or Solenoids: Use relays or solenoids to control vehicle functions remotely, such as locking/unlocking doors or disabling the engine. 2. Embedded Software: • Develop the firmware for the 8051 microcontroller using a suitable programming language like C or assembly language. • Implement the logic to read data from the sensors and process the information to detect potential security breaches. • Use UART communication to interact with the GSM module and send/receive SMS messages to control the system remotely. 3. System Functionality: • Vehicle Lock/Unlock: Enable the owner to lock or unlock the vehicle doors remotely using SMS commands. • Alarm Trigger: When the sensors detect suspicious activity, trigger the alarm to alert nearby people. • Location Tracking: If a GPS module is used, obtain real-time location data and send it to the owner's mobile phone upon request. • Remote Immobilization: Allow the owner to send a specific SMS command to disable the vehicle's ignition remotely. 4. GSM Communication: • Configure the GSM module to operate in SMS mode. • Implement a parser to interpret incoming SMS commands and execute the corresponding actions. 5. Power Supply: • Ensure that the system has a reliable power supply to operate continuously. Consider using a combination of the vehicle's power and a backup battery system. 6. Mobile App/Interface: • Develop a mobile app (Android or iOS) or use a web-based interface to interact with the system through SMS commands. Remember that the 8051 microcontroller has limited processing power and memory compared to more modern microcontrollers, so you may need to optimize your code and make efficient use of available resources.

8051 Based Vehicle🚗Accident Detection System Using GSM and GPS

8051 Based Vehicle🚗Accident Detection System Using GSM and GPS | accident detection and alert system using arduino | accident detection and alert system | arduino based vehicle accident alert system using gps | vehicle accident detection system using gsm and gps | iot based vehicle tracking and accident detection system pdf | detection | vehicle accident detection using gsm and gps | accident detection and messaging system using gsm and gps | iot based accident detection system. *********************************************************** If You Want To Purchase the Full Working Project KIT Mail Us: svsembedded@gmail.com Title Name Along With You-Tube Video Link We are Located at Telangana, Hyderabad, Boduppal. Project Changes also Made according to Student Requirements http://svsembedded.com/  https://www.svskits.in/ http://svsembedded.in/  http://www.svskit.com/ M1: +91 9491535690  M2: +91 7842358459 We Will Send Working Model Project KIT through DTDC / DHL / Blue Dart / First Flight Courier Service We Will Provide Project Soft Data through Google Drive 1. Project Abstract / Synopsis 2. Project Related Datasheets of Each Component 3. Project Sample Report / Documentation 4. Project Kit Circuit / Schematic Diagram 5. Project Kit Working Software Code 6. Project Related Software Compilers 7. Project Related Sample PPT’s 8. Project Kit Photos 9. Project Kit Working Video links Latest Projects with Year Wise YouTube video Links 157 Projects  https://svsembedded.com/ieee_2022.php 135 Projects  https://svsembedded.com/ieee_2021.php 151 Projects  https://svsembedded.com/ieee_2020.php 103 Projects  https://svsembedded.com/ieee_2019.php 61 Projects  https://svsembedded.com/ieee_2018.php 171 Projects  https://svsembedded.com/ieee_2017.php 170 Projects  https://svsembedded.com/ieee_2016.php 67 Projects  https://svsembedded.com/ieee_2015.php 55 Projects  https://svsembedded.com/ieee_2014.php 43 Projects  https://svsembedded.com/ieee_2013.php 1100+ Projects https://www.svskit.com/2022/02/900-pr... *********************************************************** Designing a vehicle accident detection system using the 8051 microcontroller, GSM, and GPS can be a challenging but rewarding project. The system aims to detect accidents and send out notifications with location details to a predefined phone number. Below is a high-level overview of the system: Components required: 1. 8051 microcontroller (for this example, we'll assume you're using the AT89S52) 2. GSM module (SIM800 or similar) 3. GPS module (NEO-6M or similar) 4. Impact sensor (such as an accelerometer) 5. Power supply 6. LCD display (optional) System Overview: 1. Accident Detection: The heart of the system is the impact sensor, which detects sudden changes in acceleration (indicative of an accident). When an accident is detected, the impact sensor will send an interrupt signal to the microcontroller. 2. GPS Location Retrieval: The GPS module is connected to the microcontroller and provides real-time location data (latitude and longitude) when queried. 3. GSM Communication: The GSM module is interfaced with the microcontroller to send SMS messages. It is responsible for transmitting the accident notification along with the GPS location to a predefined phone number. 4. LCD Display (Optional): If you want a local display in the vehicle, you can add an LCD module to show relevant information like "Accident Detected" and the GPS coordinates. System Flow: 1. The 8051 microcontroller continuously monitors the impact sensor for any sudden changes in acceleration. 2. If a significant impact is detected, the microcontroller triggers an interrupt to initiate accident handling. 3. Upon interrupt, the microcontroller will communicate with the GPS module to retrieve the current latitude and longitude information. 4. The microcontroller then sends this location information along with an accident notification message via the GSM module to the preconfigured phone number. Implementation: 1. Connect the GSM module to the 8051 microcontroller using UART communication. 2. Connect the GPS module to the microcontroller using UART communication as well. 3. Connect the impact sensor (accelerometer) to one of the microcontroller's digital pins, configured as an external interrupt source. 4. Write the embedded C code for the microcontroller to handle the interrupt, communicate with the GPS module, and send SMS via the GSM module. 5. Optionally, add code for an LCD module to display relevant information. Note: Be sure to check the datasheets and documentation of the components you are using, as the communication protocols and pin configurations may vary. Remember that this is just a basic overview, and there are additional considerations like power management, error handling, and user interface design that should be taken into account during a real-world implementation.

Intelligent Automotive Vehicle Control System Using CAN Protocol

Intelligent Automotive Vehicle Control System Using CAN Protocol with Arduino uno | Automotive control system using CAN protocol | INTELLIGENT VEHICLE CONTROL SYSTEM | can protocol | automotive projects using can protocol | vehicle speed control system using rf | embedded world | can protocol programming in embedded c | can bus | embedded systems | learn embedded systems | can protocol | embedded world | can protocol based embedded projects pdf | embedded systems explained | can protocol tutorial | automatic vehicle speed control using rf | vehicle speed control using Arduino | can bus system | vehicle safety application using can. *********************************************************** If You Want To Purchase the Full Working Project KIT Mail Us: svsembedded@gmail.com Title Name Along With You-Tube Video Link We are Located at Telangana, Hyderabad, Boduppal. Project Changes also Made according to Student Requirements http://svsembedded.com/  https://www.svskits.in/ http://svsembedded.in/  http://www.svskit.com/ M1: +91 9491535690  M2: +91 7842358459 We Will Send Working Model Project KIT through DTDC / DHL / Blue Dart / First Flight Courier Service We Will Provide Project Soft Data through Google Drive 1. Project Abstract / Synopsis 2. Project Related Datasheets of Each Component 3. Project Sample Report / Documentation 4. Project Kit Circuit / Schematic Diagram 5. Project Kit Working Software Code 6. Project Related Software Compilers 7. Project Related Sample PPT’s 8. Project Kit Photos 9. Project Kit Working Video links Latest Projects with Year Wise YouTube video Links 157 Projects  https://svsembedded.com/ieee_2022.php 135 Projects  https://svsembedded.com/ieee_2021.php 151 Projects  https://svsembedded.com/ieee_2020.php 103 Projects  https://svsembedded.com/ieee_2019.php 61 Projects  https://svsembedded.com/ieee_2018.php 171 Projects  https://svsembedded.com/ieee_2017.php 170 Projects  https://svsembedded.com/ieee_2016.php 67 Projects  https://svsembedded.com/ieee_2015.php 55 Projects  https://svsembedded.com/ieee_2014.php 43 Projects  https://svsembedded.com/ieee_2013.php 1100+ Projects https://www.svskit.com/2022/02/900-pr... *********************************************************** Developing an Intelligent Automotive Vehicle Control System using the Controller Area Network (CAN) protocol and Arduino Uno can be a fascinating project. CAN is a widely used communication protocol in the automotive industry for enabling reliable communication between various electronic control units (ECUs) within a vehicle. Here's an overview of how you can approach building such a system: Materials Needed: 1. Arduino Uno board 2. CAN-BUS Shield (e.g., MCP2515 CAN controller with TJA1050 CAN transceiver) 3. Sensors (e.g., ultrasonic sensors for obstacle detection) 4. Actuators (e.g., motors or servos for vehicle control) 5. Vehicle model (toy car or custom-built platform) 6. Power supply (battery or external power source) 7. Connecting wires Step 1: Set Up CAN Communication 1. Connect the CAN-BUS Shield to the Arduino Uno. 2. Install the necessary library for the MCP2515 CAN controller. You can use libraries like "mcp_can" to facilitate CAN communication. 3. Initialize the CAN controller and set the baud rate according to your vehicle's specifications (usually 500kbps for automotive applications). 4. Implement functions to send and receive CAN messages. Define the message format and structure to exchange data between different ECUs. Step 2: Implement Sensor Integration 1. Connect the sensors (e.g., ultrasonic sensors) to the Arduino Uno. 2. Write code to read data from the sensors. 3. Process the sensor data and convert it into appropriate CAN messages. 4. Send the sensor data as CAN messages to other ECUs or the main vehicle controller. Step 3: Implement Actuator Control 1. Connect the actuators (e.g., motors or servos) to the Arduino Uno. 2. Define the control logic for the actuators based on the received CAN messages. 3. Act on the received messages and control the actuators accordingly. Step 4: Develop Intelligent Control Logic 1. Implement intelligent control algorithms to make decisions based on sensor data and other inputs. 2. Use the data from the sensors to implement features like obstacle detection, collision avoidance, lane-keeping, etc. 3. Combine sensor data with decision-making logic to create an intelligent control system. Step 5: Assemble and Test 1. Assemble all the components on the vehicle model (toy car or custom-built platform). 2. Upload the Arduino code to the Arduino Uno. 3. Power up the system and test the functionality. 4. Debug and refine your code to ensure everything works as intended. Keep in mind that building an intelligent automotive control system requires a good understanding of both hardware and software development.