Datasheet
Table Of Contents
- RP2040 Datasheet
- Colophon
- Chapter 1. Introduction
- Chapter 2. System Description
- 2.1. Bus Fabric
- 2.2. Address Map
- 2.3. Processor subsystem
- 2.4. Cortex-M0+
- 2.4.1. Features
- 2.4.2. Functional Description
- 2.4.3. Programmer’s model
- 2.4.4. System control
- 2.4.5. NVIC
- 2.4.6. MPU
- 2.4.7. Debug
- 2.4.8. List of Registers
- 2.5. Memory
- 2.6. Boot Sequence
- 2.7. Bootrom
- 2.7.1. Bootrom Source
- 2.7.2. Processor Controlled Boot Sequence
- 2.7.3. Bootrom Contents
- 2.7.4. USB Mass Storage Interface
- 2.7.5. USB PICOBOOT Interface
- 2.8. Power Supplies
- 2.9. On-Chip Voltage Regulator
- 2.10. Power Control
- 2.11. Chip-Level Reset
- 2.12. Power-On State Machine
- 2.13. Subsystem Resets
- 2.14. Clocks
- 2.14.1. Overview
- 2.14.2. Clock sources
- 2.14.2.1. Ring Oscillator
- 2.14.2.1.1. Mitigating ROSC frequency variation due to process
- 2.14.2.1.2. Mitigating ROSC frequency variation due to voltage
- 2.14.2.1.3. Mitigating ROSC frequency variation due to temperature
- 2.14.2.1.4. Automatic mitigation of ROSC frequency variation due to PVT
- 2.14.2.1.5. Automatic overclocking using the ROSC
- 2.14.2.2. Crystal Oscillator
- 2.14.2.3. External Clocks
- 2.14.2.4. Relaxation Oscillators
- 2.14.2.5. PLLs
- 2.14.2.1. Ring Oscillator
- 2.14.3. Clock Generators
- 2.14.4. Frequency Counter
- 2.14.5. Resus
- 2.14.6. Programmer’s Model
- 2.14.7. List of registers
- 2.15. Crystal Oscillator (XOSC)
- 2.16. Ring Oscillator (ROSC)
- 2.17. PLL
- 2.18. GPIO
- 2.19. Sysinfo
- 2.20. Syscfg
- Chapter 3. PIO
- Chapter 4. Peripherals
- 4.1. USB
- 4.2. DMA
- 4.3. UART
- 4.4. I2C
- 4.4.1. Features
- 4.4.2. IP Configuration
- 4.4.3. I2C Overview
- 4.4.4. I2C Terminology
- 4.4.5. I2C Behaviour
- 4.4.6. I2C Protocols
- 4.4.7. Tx FIFO Management and START, STOP and RESTART Generation
- 4.4.8. Multiple Master Arbitration
- 4.4.9. Clock Synchronization
- 4.4.10. Operation Modes
- 4.4.11. Spike Suppression
- 4.4.12. Fast Mode Plus Operation
- 4.4.13. Bus Clear Feature
- 4.4.14. IC_CLK Frequency Configuration
- 4.4.15. DMA Controller Interface
- 4.4.16. List of Registers
- 4.5. SPI
- 4.5.1. Overview
- 4.5.2. Functional Description
- 4.5.3. Operation
- 4.5.3.1. Interface reset
- 4.5.3.2. Configuring the SSP
- 4.5.3.3. Enable PrimeCell SSP operation
- 4.5.3.4. Clock ratios
- 4.5.3.5. Programming the SSPCR0 Control Register
- 4.5.3.6. Programming the SSPCR1 Control Register
- 4.5.3.7. Frame format
- 4.5.3.8. Texas Instruments synchronous serial frame format
- 4.5.3.9. Motorola SPI frame format
- 4.5.3.10. Motorola SPI Format with SPO=0, SPH=0
- 4.5.3.11. Motorola SPI Format with SPO=0, SPH=1
- 4.5.3.12. Motorola SPI Format with SPO=1, SPH=0
- 4.5.3.13. Motorola SPI Format with SPO=1, SPH=1
- 4.5.3.14. National Semiconductor Microwire frame format
- 4.5.3.15. Examples of master and slave configurations
- 4.5.3.16. PrimeCell DMA interface
- 4.5.4. List of Registers
- 4.6. PWM
- 4.7. Timer
- 4.8. Watchdog
- 4.9. RTC
- 4.10. ADC and Temperature Sensor
- 4.11. SSI
- 4.11.1. Overview
- 4.11.2. Features
- 4.11.3. IP Modifications
- 4.11.4. Clock Ratios
- 4.11.5. Transmit and Receive FIFO Buffers
- 4.11.6. 32-Bit Frame Size Support
- 4.11.7. SSI Interrupts
- 4.11.8. Transfer Modes
- 4.11.9. Operation Modes
- 4.11.10. Partner Connection Interfaces
- 4.11.11. DMA Controller Interface
- 4.11.12. APB Interface
- 4.11.13. List of Registers
- Chapter 5. Electrical and Mechanical
- Appendix A: Register Field Types
- Appendix B: Errata
4.10.3. SAR ADC
The SAR ADC (Successive Approximation Register Analogue to Digital Converter) is a combination of digital controller,
and analogue circuit as show in Figure 113.
Figure 113. SAR ADC
Block diagram
The ADC requires a 48MHz clock ( clk_adc ), which could come from the USB PLL. Capturing a sample takes 96 clock
cycles (96 x 1 / 48MHz) = 2 μs per sample (500kS/s). The clock must be set up correctly before enabling the ADC.
Once the ADC block is provided with a clock, and its reset has been removed, writing a 1 to CS.EN will start a short internal
power-up sequence for the ADC’s analogue hardware. After a few clock cycles, CS.READY will go high, indicating the ADC
is ready to start its first conversion.
The ADC can be disabled again at any time by clearing CS.EN, to save power. CS.EN does not enable the temperature
sensor bias source (see Section 4.10.4). This is controlled separately.
4.10.3.1. One-shot Sample
Writing a 1 to CS.START_ONCE will immediately start a new conversion. CS.READY will go low, to show that a conversion
is currently in progress. After 96 cycles of clk_adc, CS.READY will go high. The 12-bit conversion result is available in
RESULT.
The ADC input to be sampled is selected by writing to CS.AINSEL, any time before the conversion starts. An AINSEL value
of 0…3 selects the ADC input on GPIO 26…29. AINSEL of 4 selects the internal temperature sensor.
NOTE
No settling time is required when switching AINSEL.
4.10.3.2. Free-running Sampling
When CS.START_MANY is set,the ADC will automatically start new conversions at regular intervals. The most recent
conversion result is always available in RESULT, but for IRQ or DMA driven streaming of samples, the ADC FIFO must be
enabled (Section 4.10.3.4).
By default (DIV = 0), new conversions start immediately upon the previous conversion finishing, so a new sample is
produced every 96 cycles. At a clock frequency of 48 MHz, this produces 500 kS/s.
Setting DIV.INT to some positive value n will trigger the ADC once per n + 1 cycles, though the ADC ignores this if a
conversion is currently in progress, so generally n will be >= 96. For example, setting DIV.INT to 47999 will run the ADC at
1 kS/s, if running from a 48 MHz clock.
The pacing timer supports fractional-rate division (first order delta sigma). When setting DIV.FRAC to a nonzero value, the
ADC will start a new conversion once per cycles on average, by changing the sample interval between
and .
RP2040 Datasheet
4.10. ADC and Temperature Sensor 584