1. Article purpose[edit source]
The purpose of this article is to:
- briefly introduce the ADC peripheral and its main features,
- indicate the peripheral instances assignment at boot time and their assignment at runtime (including whether instances can be allocated to secure contexts),
- list the software frameworks and drivers managing the peripheral,
- explain how to configure the peripheral.
2. Peripheral overview[edit source]
The ADC peripheral is a successive approximation analog-to-digital converter.
The STM32MP15 has one ADC block with two physical ADCs:
- Configurable resolution: 8, 10, 12, 14, 16 bits.
- Each ADC has up to 20 multiplexed channels (including 6 internal channels connected only to ADC2).
- The conversions can be performed in single, continuous, scan or discontinuous mode.
- The result can be read in a left- or right-aligned 32-bit data register by using CPU or DMA[1].
- The analog watchdog feature allows the application to detect if the input voltage goes beyond the user-defined, high or low thresholds.
- A common input clock for the two ADCs, which can be selected between 2 different clock[2] sources (Synchronous or Asynchronous clock).
- The common reference voltage can be provided by either VREFBUF[3] or any other external regulator[4] wired to VREF+ pin.
Each ADC supports two contexts to manage conversions:
- Regular conversions can be done in sequence, running in background
- Injected conversions have higher priority, and so have the ability to interrupt the regular sequence (either triggered in SW or HW). The regular sequence is resumed, in case it has been interrupted.
- Each context has its own configurable sequence and trigger: software, TIM[5], LPTIM[6] and EXTI[7].
Refer to the STM32MP15 reference manuals for the complete list of features, and to the software frameworks and drivers, introduced below, to see which features are implemented.
3. Peripheral usage[edit source]
This chapter is applicable in the scope of the OpenSTLinux BSP running on the Arm® Cortex®-A processor(s), and the STM32CubeMPU Package running on the Arm® Cortex®-M processor.
3.1. Boot time assignment[edit source]
3.1.1. On STM32MP15x lines [edit source]
The ADC is usually not used at boot time. But it may be used by the SSBL (see Boot chain overview), to check for power supplies for example.
Click on to expand or collapse the legend...
Check boxes illustrate the possible peripheral allocations supported by STM32 MPU Embedded Software:
- ☐ means that the peripheral can be assigned to the given boot time context.
- ☑ means that the peripheral is assigned by default to the given boot time context and that the peripheral is mandatory for the STM32 MPU Embedded Software distribution.
- ⬚ means that the peripheral can be assigned to the given boot time context, but this configuration is not supported in STM32 MPU Embedded Software distribution.
- ✓ is used for system peripherals that cannot be unchecked because they are hardware connected in the device.
The present chapter describes STMicroelectronics recommendations or choice of implementation. Additional possibilities might be described in STM32 MPU reference manuals.
Domain | Peripheral | Boot time allocation | Comment | |||
---|---|---|---|---|---|---|
Instance | Cortex-A7 secure (ROM code) |
Cortex-A7 secure (TF-A BL2) |
Cortex-A7 non-secure (U-Boot) | |||
Analog | ADC | ADC | ☐ |
3.2. Runtime assignment[edit source]
3.2.1. On STM32MP15x lines [edit source]
Click on to expand or collapse the legend...
Check boxes illustrate the possible peripheral allocations supported by STM32 MPU Embedded Software:
- ☐ means that the peripheral can be assigned to the given runtime context.
- ☑ means that the peripheral is assigned by default to the given runtime context and that the peripheral is mandatory for the STM32 MPU Embedded Software distribution.
- ⬚ means that the peripheral can be assigned to the given runtime context, but this configuration is not supported in STM32 MPU Embedded Software distribution.
- ✓ is used for system peripherals that cannot be unchecked because they are hardware connected in the device.
Refer to How to assign an internal peripheral to an execution context for more information on how to assign peripherals manually or via STM32CubeMX.
The present chapter describes STMicroelectronics recommendations or choice of implementation. Additional possiblities might be described in STM32MP15 reference manuals.
Domain | Peripheral | Runtime allocation | Comment | |||
---|---|---|---|---|---|---|
Instance | Cortex-A7 secure (OP-TEE) |
Cortex-A7 non-secure (Linux) |
Cortex-M4 (STM32Cube) | |||
Analog | ADC | ADC | ☐ | ☐ | Assignment (single choice) |
4. Software frameworks and drivers[edit source]
Below are listed the software frameworks and drivers managing the ADC peripheral for the embedded software components listed in the above tables.
- Linux®: IIO framework
- STM32Cube: HAL ADC driver
- U-Boot: U-Boot ADC driver
5. How to assign and configure the peripheral[edit source]
The peripheral assignment can be done via the STM32CubeMX graphical tool (and manually completed if needed).
This tool also helps to configure the peripheral:
- partial device trees (pin control and clock tree) generation for the OpenSTLinux software components,
- HAL initialization code generation for the STM32CubeMPU Package.
The configuration is applied by the firmware running in the context in which the peripheral is assigned.
For the Linux kernel and U-boot configuration, please refer to ADC device tree configuration article.
6. How to go further[edit source]
See application notes:
- How to get the best ADC accuracy in STM32[8].
- Getting started with STM32MP15 series hardware development (AN5031)[9].
It deals with analog domain power supply and reference voltage.
7. References[edit source]
- ↑ DMA internal peripheral
- ↑ RCC internal peripheral
- ↑ VREFBUF internal peripheral
- ↑ Regulator overview
- ↑ TIM internal peripheral
- ↑ LPTIM internal peripheral
- ↑ EXTI internal peripheral
- ↑ How to get the best ADC accuracy in STM32, by STMicroelectronics
- ↑ Getting started with STM32MP15 series hardware development, by STMicroelectronics