About: I ain't no physicist, but I knows what matters. :p By the way, I'm an Electronic Engineer . Interested in Electronic Hobby's and DIY Projects . I'm Focusing mostly on Simulations of Projects and Further more …

Remember when printers, mice, and modems had thick cables with those huge clunky connectors? The ones that literally had to be screwed into your computer? Those devices were probably using UARTs to communicate with your computer. While USB has almost completely replaced those old cables and connectors, UARTs are definitely not a thing of the past. You’ll find UARTs being used in many DIY electronics projects to connect GPS modules, Bluetooth modules, and RFID card reader modules to your Raspberry Pi, Arduino, or other microcontrollers.

UART stands for Universal Asynchronous Receiver/Transmitter. It’s not a communication protocol like SPI and I2C, but a physical circuit in a microcontroller, or a stand-alone IC. A UART’s main purpose is to transmit and receive serial data.

One of the best things about UART is that it only uses two wires to transmit data between devices. The principles behind UART are easy to understand, but if you haven’t read part one of this series, Basics of the SPI Communication Protocol, that might be a good place to start.


In UART communication, two UARTs communicate directly with each other. The transmitting UART converts parallel data from a controlling device like a CPU into serial form, transmits it in serial to the receiving UART, which then converts the serial data back into parallel data for the receiving device. Only two wires are needed to transmit data between two UARTs. Data flows from the Tx pin of the transmitting UART to the Rx pin of the receiving UART:

Step 2: Data Flows From the Tx Pin of the Transmitting UART to the Rx Pin of the Receiving UART:

Step 3:

UARTs transmit data asynchronously, which means there is no clock signal to synchronize the output of bits from the transmitting UART to the sampling of bits by the receiving UART. Instead of a clock signal, the transmitting UART adds start and stop bits to the data packet being transferred. These bits define the beginning and end of the data packet so the receiving UART knows when to start reading the bits.

When the receiving UART detects a start bit, it starts to read the incoming bits at a specific frequency known as the baud rate. Baud rate is a measure of the speed of data transfer, expressed in bits per second (bps). Both UARTs must operate at about the same baud rate. The baud rate between the transmitting and receiving UARTs can only differ by about 10% before the timing of bits gets too far off.

Step 4:

Both UARTs must also must be configured to transmit and receive the same data packet structure.


The UART that is going to transmit data receives the data from a data bus. The data bus is used to send data to the UART by another device like a CPU, memory, or microcontroller. Data is transferred from the data bus to the transmitting UART in parallel form. After the transmitting UART gets the parallel data from the data bus, it adds a start bit, a parity bit, and a stop bit, creating the data packet. Next, the data packet is output serially, bit by bit at the Tx pin. The receiving UART reads the data packet bit by bit at its Rx pin. The receiving UART then converts the data back into parallel form and removes the start bit, parity bit, and stop bits. Finally, the receiving UART transfers the data packet in parallel to the data bus on the receiving end:

Step 6: Image How UART Works

Step 7:

UART transmitted data is organized into packets. Each packet contains 1 start bit, 5 to 9 data bits (depending on the UART), an optional parity bit, and 1 or 2 stop bits:

Step 8: UART Transmitted Data Is Organized Into Packets Image

Step 9:


The UART data transmission line is normally held at a high voltage level when it’s not transmitting data. To start the transfer of data, the transmitting UART pulls the transmission line from high to low for one clock cycle. When the receiving UART detects the high to low voltage transition, it begins reading the bits in the data frame at the frequency of the baud rate.


The data frame contains the actual data being transferred. It can be 5 bits up to 8 bits long if a parity bit is used. If no parity bit is used, the data frame can be 9 bits long. In most cases, the data is sent with the least significant bit first.


Parity describes the evenness or oddness of a number. The parity bit is a way for the receiving UART to tell if any data has changed during transmission. Bits can be changed by electromagnetic radiation, mismatched baud rates, or long distance data transfers. After the receiving UART reads the data frame, it counts the number of bits with a value of 1 and checks if the total is an even or odd number. If the parity bit is a 0 (even parity), the 1 bits in the data frame should total to an even number. If the parity bit is a 1 (odd parity), the 1 bits in the data frame should total to an odd number. When the parity bit matches the data, the UART knows that the transmission was free of errors. But if the parity bit is a 0, and the total is odd; or the parity bit is a 1, and the total is even, the UART knows that bits in the data frame have changed.


o signal the end of the data packet, the sending UART drives the data transmission line from a low voltage to a high voltage for at least two bit durations.


1. The transmitting UART receives data in parallel from the data bus:

Step 11: Image Transmitting UART Receives Data in Parallel From the Data Bus

Step 12: 2. the Transmitting UART Adds the Start Bit, Parity Bit, and the Stop Bit(s) to the Data Frame:

Step 13: 3. the Entire Packet Is Sent Serially From the Transmitting UART to the Receiving UART. the Receiving UART Samples the Data Line at the Pre-configured Baud Rate:

Step 14: 4. the Receiving UART Discards the Start Bit, Parity Bit, and Stop Bit From the Data Frame:

Step 15: 5. the Receiving UART Converts the Serial Data Back Into Parallel and Transfers It to the Data Bus on the Receiving End:


No communication protocol is perfect, but UARTs are pretty good at what they do. Here are some pros and cons to help you decide whether or not they fit the needs of your project:


Only uses two wires No clock signal is necessary Has a parity bit to allow for error checking The structure of the data packet can be changed as long as both sides are set up for it Well documented and widely used method DISADVANTAGES

The size of the data frame is limited to a maximum of 9 bits Doesn’t support multiple slave or multiple master systems The baud rates of each UART must be within 10% of each other Continue on to part three of this series, Basics of the I2C Communication Protocol to learn about another way electronic devices communicate. Or if you haven’t already, check out part one, Basics of the SPI Communication Protocol.

And as always, let me know in the comments if you have questions or anything else to add! If you liked this article and want to see more like it, be sure to Follow