SBAA565 November   2022 ADC081C021 , ADC081C027 , ADC101C021 , ADC101C027 , ADC121C021 , ADC121C021-Q1 , ADC121C027 , ADC128D818 , ADS1000 , ADS1000-Q1 , ADS1013 , ADS1014 , ADS1015 , ADS1015-Q1 , ADS1100 , ADS1110 , ADS1112 , ADS1113 , ADS1114 , ADS1115 , ADS1115-Q1 , ADS7823 , ADS7827 , ADS7828 , ADS7828-Q1 , ADS7830 , ADS7924 , AFE539A4 , DAC081C081 , DAC081C085 , DAC101C081 , DAC101C081Q , DAC101C085 , DAC121C081 , DAC121C085 , DAC43204 , DAC43401 , DAC43401-Q1 , DAC43608 , DAC43701 , DAC43701-Q1 , DAC53002 , DAC53004 , DAC53202 , DAC53204 , DAC53204W , DAC53401 , DAC53401-Q1 , DAC53608 , DAC53701 , DAC53701-Q1 , DAC5571 , DAC5573 , DAC5574 , DAC5578 , DAC60501 , DAC60502 , DAC63002 , DAC63004 , DAC63202 , DAC63204 , DAC6571 , DAC6573 , DAC6574 , DAC6578 , DAC70501 , DAC70502 , DAC7571 , DAC7573 , DAC7574 , DAC7578 , DAC7678 , DAC80501 , DAC80502 , DAC8571 , DAC8574

 

  1.   Abstract
  2.   Trademarks
  3. 1I2C Overview
    1. 1.1 History
    2. 1.2 I2C Speed Modes
  4. 2I2C Physical Layer
    1. 2.1 Two-Wire Communication
    2. 2.2 Open-Drain Connection
    3. 2.3 Non-Destructive Bus Contention
  5. 3I2C Protocol
    1. 3.1 I2C START and STOP
    2. 3.2 Logical Ones and Zeros
    3. 3.3 I2C Communication Frames
  6. 4I2C Examples
    1. 4.1 DAC80501 Example
      1. 4.1.1 DAC80501 DAC Data Register
      2. 4.1.2 DAC80501 I2C Example Write
    2. 4.2 ADS1115 Example
      1. 4.2.1 ADS1115 Configuration Register
      2. 4.2.2 ADS1115 I2C Example Read
      3. 4.2.3 ADS1115 Conversion Result
  7. 5Reserved Addresses
    1. 5.1 General Call
    2. 5.2 START Byte
    3. 5.3 C-Bus Address, Different Bus Format, Future Purposes
    4. 5.4 HS-Mode Controller Code
    5. 5.5 Device ID
    6. 5.6 10-Bit Target Addressing
      1. 5.6.1 10-Bit Target Addressing Write
      2. 5.6.2 10-Bit Target Addressing Read
  8. 6Advanced Topics
    1. 6.1 Clock Synchronization and Arbitration
    2. 6.2 Clock Stretching
    3. 6.3 Electrical Specifications
    4. 6.4 Voltage Level Translation
      1. 6.4.1 Example 1
      2. 6.4.2 Example 2
      3. 6.4.3 Example 3
      4. 6.4.4 Example 4
    5. 6.5 Pullup Resistor Sizing
      1. 6.5.1 Minimum Pullup Resistance Sizing
      2. 6.5.2 Maximum Pullup Resistance Sizing
  9. 7Protocols Similar to I2C
  10. 8Summary

1.2 I2C Speed Modes

I2C has several speed modes starting with the Standard-mode (Sm), which is a serial protocol that operates up to 100 kilobits per second (kbps). This mode is followed by the Fast-mode (Fm) which tops out at 400 kilobits per second. Fast-mode can be used by the controller if the bus capacitance and drive capability allow for the faster speed. Both of these protocols are widely supported.

The Fast-mode Plus (Fm+) mode allows for communication as high as 1 megabit per second (Mbps). To achieve this speed, drivers in the devices require extra strength to comply with faster rise and fall times.

These three modes are relatively similar, using a communication structure that is the same. However, all have different timing specifications for each of the modes and hardware implementation of the I2C in the devices are different to accommodate the different speeds.

I2C also has two other modes for higher data rates. High-speed mode (Hs-mode) has a data rate to 3.4 megabits per second. In this mode, the controller device must first use a controller code to allow for high-speed data transfer. This enables high-speed mode in the target device. This mode can also require an active pullup to drive the communication lines at a higher data rate.

Ultra-Fast mode (UFm) is the fastest mode of operation and transfers data up to 5Mbps. This mode is write-only and omits some I2C features in the communication protocol.

Table 1-1 shows the different I2C modes and their respective data rates

Table 1-1 Maximum Transmission Rates for Different I2C Modes
I2C Mode Maximum Bit Rate
Standard-mode 100kbps
Fast-mode 400kbps
Fast-mode Plus 1Mbps
High-speed mode 3.4Mbps
Ultra-Fast mode 5Mbps