Datasheet RP2040 (Raspberry Pi) - 636

制造商Raspberry Pi
描述A microcontroller by Raspberry Pi
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Power Supply. Supplies. Min. Typ. Max. Units. 5.4. Power Consumption. NOTE. Raspberry Pi Pico Datasheet. Hardware design with RP2040

Power Supply Supplies Min Typ Max Units 5.4 Power Consumption NOTE Raspberry Pi Pico Datasheet Hardware design with RP2040

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link to page 179 link to page 636 RP2040 Datasheet
Power Supply Supplies Min Typ Max Units
USB_VDD USB PHY 3.135 3.3 3.63 V ADC_AVDDb ADC 1.62 3.3 3.63 V a If IOVDD <2.5V, GPIO VOLTAGE_SELECT registers should be adjusted accordingly. See Section 2.9 for details. b ADC performance will be compromised at voltages below 2.97V
5.4. Power Consumption
The following data shows the current consumption of various power supplies on 3 each of typical (tt), fast (ff) and slow (ss) corner RP2040 devices, with four different software use-cases. 
NOTE
For power consumption of the Raspberry Pi Pico, please see the
Raspberry Pi Pico Datasheet
. Firstly, 'Popcorn' (Media player demo) using the VGA, SD Card, and Audio board. This demo uses VGA video, I2S audio and 4-bit SD Card access, with a system clock frequency of 48MHz. 
NOTE
For more details of the VGA board see the
Hardware design with RP2040
book. Secondly, the BOOTSEL mode of RP2040. These measurements are made both with and without USB activity on the bus, using a Raspberry Pi 4 as a host. The third use-case uses the hello_dormant binary which puts RP2040 into a low power state, DORMANT mode. The final use-case uses the hello_sleep binary code which puts RP2040 into a low power state, SLEEP mode. Table 635 has two columns per power supply, 'Typical Average Current' and 'Maximum Average Current'. The former is the current averaged over several seconds that you might expect a typical RP2040 to consume at room temperature and nominal voltage (e.g., DVDD=1.1V, IOVDD=3.3V, etc). The 'Maximum Average Current' is the maximum current consumption (again averaged over several seconds) you might expect to see on a worst-case RP2040 device, across the temperature extremes, and maximum voltage (e.g., DVDD=1.21V, etc). 
NOTE
The 'Popcorn' consumption measurements are heavily dependant on the video being displayed at the time. The 'Typical' values are obtained over several seconds of video, with varied colour and intensity. The 'Maximum' values are measured during periods of white video, when the required current is at its highest. Table 635. Power
Software Use- Typical Max. Average Typical Max. Average Typical Max. Average Units
Consumption
case Average DVDD DVDD current Average IOVDD current Average USB_VDD Current IOVDD Current USB_VDD current Current
Popcorn 10.9 16.6 24.8 35.5 - - mA BOOTSEL 9.4 14.7 1.2 4.3 1.4 2.0 mA mode - Active BOOTSEL 9.0 14.3 1.2 4.3 0.2 0.6 mA mode - Idle Dormant 0.18 4.2 - - - - mA 5.4. Power Consumption
635
Document Outline RP2040 Datasheet Colophon Legal Disclaimer Notice Table of Contents Chapter 1. Introduction 1.1. Why is the chip called RP2040? 1.2. Summary 1.3. The Chip 1.4. Pinout Reference 1.4.1. Pin Locations 1.4.2. Pin Descriptions 1.4.3. GPIO Functions Chapter 2. System Description 2.1. Bus Fabric 2.1.1. AHB-Lite Crossbar 2.1.2. Atomic Register Access 2.1.3. APB Bridge 2.1.4. Narrow IO Register Writes 2.1.5. List of Registers 2.2. Address Map 2.2.1. Summary 2.2.2. Detail 2.3. Processor subsystem 2.3.1. SIO 2.3.2. Interrupts 2.3.3. Event Signals 2.3.4. Debug 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. DMA 2.5.1. Configuring Channels 2.5.2. Starting Channels 2.5.3. Data Request (DREQ) 2.5.4. Interrupts 2.5.5. Additional Features 2.5.6. Example Use Cases 2.5.7. List of Registers 2.6. Memory 2.6.1. ROM 2.6.2. SRAM 2.6.3. Flash 2.7. Boot Sequence 2.8. Bootrom 2.8.1. Processor Controlled Boot Sequence 2.8.2. Bootrom Contents 2.8.3. USB Mass Storage Interface 2.8.4. USB PICOBOOT Interface 2.9. Power Supplies 2.9.1. Digital IO Supply (IOVDD) 2.9.2. Digital Core Supply (DVDD) 2.9.3. On-Chip Voltage Regulator Input Supply (VREG_VIN) 2.9.4. USB PHY Supply (USB_VDD) 2.9.5. ADC Supply (ADC_AVDD) 2.9.6. Power Supply Sequencing 2.9.7. Power Supply Schemes 2.10. Core Supply Regulator 2.10.1. Application Circuit 2.10.2. Operating Modes 2.10.3. Output Voltage Select 2.10.4. Status 2.10.5. Current Limit 2.10.6. List of Registers 2.10.7. Detailed Specifications 2.11. Power Control 2.11.1. Top-level Clock Gates 2.11.2. SLEEP State 2.11.3. DORMANT State 2.11.4. Memory Power Down 2.11.5. Programmer’s Model 2.12. Chip-Level Reset 2.12.1. Overview 2.12.2. Power-on Reset 2.12.3. Brown-out Detection 2.12.4. Supply Monitor 2.12.5. External Reset 2.12.6. Rescue Debug Port Reset 2.12.7. Source of Last Reset 2.12.8. List of Registers 2.13. Power-On State Machine 2.13.1. Overview 2.13.2. Power On Sequence 2.13.3. Register Control 2.13.4. Interaction with Watchdog 2.13.5. List of Registers 2.14. Subsystem Resets 2.14.1. Overview 2.14.2. Programmer’s Model 2.14.3. List of Registers 2.15. Clocks 2.15.1. Overview 2.15.2. Clock sources 2.15.3. Clock Generators 2.15.4. Frequency Counter 2.15.5. Resus 2.15.6. Programmer’s Model 2.15.7. List of Registers 2.16. Crystal Oscillator (XOSC) 2.16.1. Overview 2.16.2. Usage 2.16.3. Startup Delay 2.16.4. XOSC Counter 2.16.5. DORMANT mode 2.16.6. Programmer’s Model 2.16.7. List of Registers 2.17. Ring Oscillator (ROSC) 2.17.1. Overview 2.17.2. ROSC/XOSC trade-offs 2.17.3. Modifying the frequency 2.17.4. ROSC divider 2.17.5. Random Number Generator 2.17.6. ROSC Counter 2.17.7. DORMANT mode 2.17.8. List of Registers 2.18. PLL 2.18.1. Overview 2.18.2. Calculating PLL parameters 2.18.3. Configuration 2.18.4. List of Registers 2.19. GPIO 2.19.1. Overview 2.19.2. Function Select 2.19.3. Interrupts 2.19.4. Pads 2.19.5. Software Examples 2.19.6. List of Registers 2.20. Sysinfo 2.20.1. Overview 2.20.2. List of Registers 2.21. Syscfg 2.21.1. Overview 2.21.2. List of Registers 2.22. TBMAN 2.22.1. List of Registers Chapter 3. PIO 3.1. Overview 3.2. Programmer’s Model 3.2.1. PIO Programs 3.2.2. Control Flow 3.2.3. Registers 3.2.4. Stalling 3.2.5. Pin Mapping 3.2.6. IRQ Flags 3.2.7. Interactions Between State Machines 3.3. PIO Assembler (pioasm) 3.3.1. Directives 3.3.2. Values 3.3.3. Expressions 3.3.4. Comments 3.3.5. Labels 3.3.6. Instructions 3.3.7. Pseudoinstructions 3.4. Instruction Set 3.4.1. Summary 3.4.2. JMP 3.4.3. WAIT 3.4.4. IN 3.4.5. OUT 3.4.6. PUSH 3.4.7. PULL 3.4.8. MOV 3.4.9. IRQ 3.4.10. SET 3.5. Functional Details 3.5.1. Side-set 3.5.2. Program Wrapping 3.5.3. FIFO Joining 3.5.4. Autopush and Autopull 3.5.5. Clock Dividers 3.5.6. GPIO Mapping 3.5.7. Forced and EXEC’d Instructions 3.6. Examples 3.6.1. Duplex SPI 3.6.2. WS2812 LEDs 3.6.3. UART TX 3.6.4. UART RX 3.6.5. Manchester Serial TX and RX 3.6.6. Differential Manchester (BMC) TX and RX 3.6.7. I2C 3.6.8. PWM 3.6.9. Addition 3.6.10. Further Examples 3.7. List of Registers Chapter 4. Peripherals 4.1. USB 4.1.1. Overview 4.1.2. Architecture 4.1.3. Programmer’s Model 4.1.4. List of Registers References 4.2. UART 4.2.1. Overview 4.2.2. Functional description 4.2.3. Operation 4.2.4. UART hardware flow control 4.2.5. UART DMA Interface 4.2.6. Interrupts 4.2.7. Programmer’s Model 4.2.8. List of Registers 4.3. I2C 4.3.1. Features 4.3.2. IP Configuration 4.3.3. I2C Overview 4.3.4. I2C Terminology 4.3.5. I2C Behaviour 4.3.6. I2C Protocols 4.3.7. Tx FIFO Management and START, STOP and RESTART Generation 4.3.8. Multiple Master Arbitration 4.3.9. Clock Synchronization 4.3.10. Operation Modes 4.3.11. Spike Suppression 4.3.12. Fast Mode Plus Operation 4.3.13. Bus Clear Feature 4.3.14. IC_CLK Frequency Configuration 4.3.15. DMA Controller Interface 4.3.16. Operation of Interrupt Registers 4.3.17. List of Registers 4.4. SPI 4.4.1. Overview 4.4.2. Functional Description 4.4.3. Operation 4.4.4. List of Registers 4.5. PWM 4.5.1. Overview 4.5.2. Programmer’s Model 4.5.3. List of Registers 4.6. Timer 4.6.1. Overview 4.6.2. Counter 4.6.3. Alarms 4.6.4. Programmer’s Model 4.6.5. List of Registers 4.7. Watchdog 4.7.1. Overview 4.7.2. Tick generation 4.7.3. Watchdog Counter 4.7.4. Scratch Registers 4.7.5. Programmer’s Model 4.7.6. List of Registers 4.8. RTC 4.8.1. Storage Format 4.8.2. Leap year 4.8.3. Interrupts 4.8.4. Reference clock 4.8.5. Programmer’s Model 4.8.6. List of Registers 4.9. ADC and Temperature Sensor 4.9.1. Features 4.9.2. ADC controller 4.9.3. SAR ADC 4.9.4. Temperature Sensor 4.9.5. List of Registers 4.10. SSI 4.10.1. Overview 4.10.2. Features 4.10.3. IP Modifications 4.10.4. Clock Ratios 4.10.5. Transmit and Receive FIFO Buffers 4.10.6. 32-Bit Frame Size Support 4.10.7. SSI Interrupts 4.10.8. Transfer Modes 4.10.9. Operation Modes 4.10.10. Partner Connection Interfaces 4.10.11. DMA Controller Interface 4.10.12. APB Interface 4.10.13. List of Registers Chapter 5. Electrical and Mechanical 5.1. Package 5.1.1. Recommended PCB Footprint 5.1.2. Compliance 5.2. Pinout 5.2.1. Pin Locations 5.2.2. Pin Definitions 5.2.3. Pin Specifications 5.3. Power Supplies 5.4. Power Consumption 5.4.1. Power Consumption versus frequency Appendix A: Register Field Types Standard types RW RO WO Clear types SC WC FIFO types RF WF RWF Appendix B: Errata Bootrom RP2040-E9 Clocks RP2040-E7 RP2040-E10 GPIO / ADC RP2040-E6 USB RP2040-E2 RP2040-E3 RP2040-E4 RP2040-E5 Watchdog RP2040-E1 XIP Flash RP2040-E8 Appendix C: Documentation Release History