knowledge/technology/internet/UDP.md

---
obj: concept
wiki: https://wikipedia.org/wiki/User_Datagram_Protocol
rfc: https://datatracker.ietf.org/doc/html/rfc768
---

# UDP
The User Datagram Protocol (UDP) is a connectionless transport layer protocol in the [Internet Protocol](Internet%20Protocol.md) (IP) suite. Unlike Transmission Control Protocol ([TCP](TCP.md)), UDP does not establish a connection before sending data and does not guarantee the delivery of data. Instead, it provides a simple and lightweight mechanism for transmitting data quickly.

## Key Characteristics
### 1. **Connectionless:**
- UDP is connectionless, meaning it does not establish a connection before sending data. Each UDP packet is treated independently.
### 2. **Unreliable:**
- UDP does not guarantee the delivery of data, and there is no mechanism for retransmission if packets are lost or arrive out of order.
### 3. **Low Overhead:**
- UDP has minimal overhead compared to [TCP](TCP.md), making it suitable for applications where speed and low latency are prioritized over reliability.
### 4. **Broadcast and Multicast Support:**
- UDP supports broadcast and multicast communication, allowing a single UDP packet to be sent to multiple recipients simultaneously.
### 5. **No Flow Control:**
- UDP does not implement flow control mechanisms, so it may send data at a rate that the recipient cannot handle.

## Use Cases
### 1. **Real-Time Applications:**
- UDP is commonly used in real-time applications where low latency is critical, such as online gaming, video conferencing, and voice over IP (VoIP).
### 2. **Streaming Media:**
- Streaming services often use UDP for delivering media content due to its speed and the ability to handle occasional packet loss without severe impact.
### 3. **Network Monitoring:**
- UDP is used in network monitoring tools and protocols, such as the Domain Name System ([DNS](DNS.md)) and Simple Network Management Protocol (SNMP).
### 4. **IoT Devices:**
- Internet of Things (IoT) devices may use UDP for lightweight communication, especially when reliability is not the primary concern.

## UDP Header
The UDP header includes the following fields:
- **Source and Destination Port Numbers:** Identify the source and destination applications on the devices.
- **Length:** Specifies the length of the UDP header and data.
- **Checksum:** Provides a simple error-checking mechanism for the UDP header and data.

## Comparison with [TCP](TCP.md)
- **Reliability:** UDP is unreliable and does not guarantee the delivery of data, while TCP provides reliable, connection-oriented communication.
- **Overhead:** UDP has lower overhead than [TCP](TCP.md) since it lacks features such as connection setup, acknowledgment, and flow control.
- **Use Cases:** UDP is suitable for real-time applications and scenarios where low latency is crucial, while [TCP](TCP.md) is preferred for applications requiring reliable data transfer.
init 2023-12-04 10:02:23 +00:00			`---`
			`obj: concept`
			`wiki: https://wikipedia.org/wiki/User_Datagram_Protocol`
			`rfc: https://datatracker.ietf.org/doc/html/rfc768`
			`---`

			`# UDP`
add ip 2024-06-02 18:43:53 +00:00			`The User Datagram Protocol (UDP) is a connectionless transport layer protocol in the [Internet Protocol](Internet%20Protocol.md) (IP) suite. Unlike Transmission Control Protocol ([TCP](TCP.md)), UDP does not establish a connection before sending data and does not guarantee the delivery of data. Instead, it provides a simple and lightweight mechanism for transmitting data quickly.`
init 2023-12-04 10:02:23 +00:00
			`## Key Characteristics`
			`### 1. Connectionless:`
			`- UDP is connectionless, meaning it does not establish a connection before sending data. Each UDP packet is treated independently.`
			`### 2. Unreliable:`
			`- UDP does not guarantee the delivery of data, and there is no mechanism for retransmission if packets are lost or arrive out of order.`
			`### 3. Low Overhead:`
			`- UDP has minimal overhead compared to [TCP](TCP.md), making it suitable for applications where speed and low latency are prioritized over reliability.`
			`### 4. Broadcast and Multicast Support:`
			`- UDP supports broadcast and multicast communication, allowing a single UDP packet to be sent to multiple recipients simultaneously.`
			`### 5. No Flow Control:`
			`- UDP does not implement flow control mechanisms, so it may send data at a rate that the recipient cannot handle.`

			`## Use Cases`
			`### 1. Real-Time Applications:`
			`- UDP is commonly used in real-time applications where low latency is critical, such as online gaming, video conferencing, and voice over IP (VoIP).`
			`### 2. Streaming Media:`
			`- Streaming services often use UDP for delivering media content due to its speed and the ability to handle occasional packet loss without severe impact.`
			`### 3. Network Monitoring:`
			`- UDP is used in network monitoring tools and protocols, such as the Domain Name System ([DNS](DNS.md)) and Simple Network Management Protocol (SNMP).`
			`### 4. IoT Devices:`
			`- Internet of Things (IoT) devices may use UDP for lightweight communication, especially when reliability is not the primary concern.`

			`## UDP Header`
			`The UDP header includes the following fields:`
			`- Source and Destination Port Numbers: Identify the source and destination applications on the devices.`
			`- Length: Specifies the length of the UDP header and data.`
			`- Checksum: Provides a simple error-checking mechanism for the UDP header and data.`

			`## Comparison with [TCP](TCP.md)`
			`- Reliability: UDP is unreliable and does not guarantee the delivery of data, while TCP provides reliable, connection-oriented communication.`
			`- Overhead: UDP has lower overhead than [TCP](TCP.md) since it lacks features such as connection setup, acknowledgment, and flow control.`
			`- Use Cases: UDP is suitable for real-time applications and scenarios where low latency is crucial, while [TCP](TCP.md) is preferred for applications requiring reliable data transfer.`