A servo motor is a type of motor that is designed to provide precise control of position and speed. It is a rotary actuator that can rotate to a specified angle with a high degree of accuracy. Servo motors are commonly used in a wide variety of applications, including robotics, factory automation, camera stabilization systems, and remote-controlled vehicles, to name a few.
When it comes to accurate timekeeping in the world of electronics, the DS3231 real-time clock (RTC) module is a reliable and precise solution. This compact yet robust module not only keeps time with exceptional accuracy but also integrates smoothly with popular microcontrollers like the Arduino Nano. In this article, we'll explore the features, wiring, and potential applications of the DS3231.
The MPU-60X0 is the world's first integrated 6-axis MotionTracking device that combines a 3-axis gyroscope, 3-axis accelerometer and a Digital Motion Processor (DMP) all in a small package. It helps to measure velocity, orientation, acceleration, displacement and other motion like features
The MPU-6050 features three 16-bit analog-to-digital converters (ADCs) for digitizing the gyroscope outputs and three 16-bit ADCs for digitizing the accelerometer outputs. For precision tracking of both fast and slow motions, the parts feature a user-programmable gyroscope full-scale range and a user-programmable accelerometer full-scale range.
A piezo buzzer is a small device that converts electrical signals into sound waves. Unlike traditional speakers, piezo buzzers operate on the piezoelectric effect. When a voltage is applied, the buzzer's piezoelectric crystal deforms, producing sound waves. This simplicity makes piezo buzzers cost-effective, lightweight, and ideal for applications where the space is limited.
A potentiometer is a simple knob that provides a variable resistance, which we can read into the Arduino board as an analog value. They can be attuned from zero ohms to whatever maximum resistance that is specific to it. For example, a potentiometer of 10 kΩ can be adjusted from 0 Ω to its maximum of 10 kΩ.
The integration of components with Arduino opens a world of possibilities. One often overlooked but incredibly useful component is the vibration motor. Vibration motors are compact, motorized devices designed to generate vibrations. This device, often found in smartphones and game controllers, can add a tactile dimension to your projects, providing physical feedback that enhances user experience. In this article, we'll explore the basics of vibration motors and explore into how you can effortlessly connect them to Arduino for a wide range of applications.
In the world of DIY electronics, Arduino stands as a go-to tool for creators and hobbyists. Today, we're exploring the integration of a 4x4 membrane keypad module with an Arduino, a combination that introduces an interactive layer to your electronic projects.
The GY-68 module, also known as the BMP180 module, is a popular sensor module used for measuring atmospheric pressure, temperature, and altitude. It features a highly precise digital barometric pressure sensor that can be easily integrated with an Arduino board. In this tutorial, we will guide you through the process of connecting the GY-68 module to an Arduino, enabling you to gather accurate environmental data for your projects. So, let's get started!
The RF-Nano module is a compact, affordable module that combines an NRF24L01 wireless transceiver with an Arduino-compatible microcontroller. Using the NRF24L01 protocol, the RF-Nano operates on the 2.4 GHz band, making it a practical choice for creating simple, low-power wireless networks. This module is popular among hobbyists and engineers for tasks like home automation, remote control applications, and IoT sensor networks. It’s especially suited for applications where simple, secure data sharing between sensors or remote control devices is required and where a compact, low-cost solution is preferred.
Laser modules emit highly focused beams of light, making them ideal for a wide range of applications. One of the key aspects of a laser module is its power output, typically measured in milliwatts (mW). Arduino compatible laser modules typically have a power output within the lower range ensuring safety and compatibility with the microcontroller board. It's important to note that modules require safety precautions due to their increased risk of eye damage and potential fire hazards for higher-power lasers.
