Datasheet Summary SAM D21EL, SAM D21GL (Microchip) - 5
| Manufacturer | Microchip |
| Description | 32-bit ARM-Based Microcontrollers |
| Pages / Page | 38 / 5 — 32-bit ARM-Based Microcontrollers. Description. Datasheet Summary |
| Revision | 02-01-2017 |
| File Format / Size | PDF / 851 Kb |
| Document Language | English |
32-bit ARM-Based Microcontrollers. Description. Datasheet Summary
Model Line for this Datasheet
- ATSAMD21E15A-MFT ATSAMD21E15B-AF ATSAMD21E15B-AFT ATSAMD21E15B-AU ATSAMD21E15B-AUT ATSAMD21E15B-MF ATSAMD21E15B-MFT ATSAMD21E15B-MU ATSAMD21E15B-MUT ATSAMD21E15B-UUT ATSAMD21E15C-UUT
- ATSAMD21E16B-AF ATSAMD21E16B-AFT ATSAMD21E16B-AU ATSAMD21E16B-AUT ATSAMD21E16B-MF ATSAMD21E16B-MFT ATSAMD21E16B-MU ATSAMD21E16B-MUT ATSAMD21E16B-UUT ATSAMD21E16C-UUT
- ATSAMD21E17A-AF ATSAMD21E17A-AFT ATSAMD21E17A-AU ATSAMD21E17A-AUT ATSAMD21E17A-MF ATSAMD21E17A-MFT ATSAMD21E17A-MU ATSAMD21E17A-MUT
- ATSAMD21E18A-AF ATSAMD21E18A-AFT ATSAMD21E18A-AU ATSAMD21E18A-AUT ATSAMD21E18A-MF ATSAMD21E18A-MFT ATSAMD21E18A-MU ATSAMD21E18A-MUT
- ATSAMD21G15B-AF ATSAMD21G15B-AFT ATSAMD21G15B-AU ATSAMD21G15B-AUT ATSAMD21G15B-MF ATSAMD21G15B-MFT ATSAMD21G15B-MU ATSAMD21G15B-MUT
- ATSAMD21G16B-AF ATSAMD21G16B-AFT ATSAMD21G16B-AU ATSAMD21G16B-AUT ATSAMD21G16B-MF ATSAMD21G16B-MFT ATSAMD21G16B-MU ATSAMD21G16B-MUT
- ATSAMD21G17A-AF ATSAMD21G17A-AFT ATSAMD21G17A-AU ATSAMD21G17A-AUT ATSAMD21G17A-MF ATSAMD21G17A-MFT ATSAMD21G17A-MU ATSAMD21G17A-MUT ATSAMD21G17A-UUT
- ATSAMD21G18A-AF ATSAMD21G18A-AFT ATSAMD21G18A-AU ATSAMD21G18A-AUT ATSAMD21G18A-MF ATSAMD21G18A-MFT ATSAMD21G18A-MU ATSAMD21G18A-MUT ATSAMD21G18A-UUT
- ATSAMD21J15B-AF ATSAMD21J15B-AFT ATSAMD21J15B-AU ATSAMD21J15B-AUT ATSAMD21J15B-MF ATSAMD21J15B-MFT ATSAMD21J15B-MU ATSAMD21J15B-MUT
- ATSAMD21J16B-AF ATSAMD21J16B-AFT ATSAMD21J16B-AU ATSAMD21J16B-AUT ATSAMD21J16B-MF ATSAMD21J16B-MFT ATSAMD21J16B-MU ATSAMD21J16B-MUT
Text Version of Document
32-bit ARM-Based Microcontrollers 1. Description
The SAM D21L is a series of low-power microcontrollers using the 32-bit ARM® Cortex®-M0+ processor, and offered in 32- and 48-pin packages with up to 64KB Flash and 8KB of SRAM. The SAM D21L operate at a maximum frequency of 48MHz and reach 2.46 CoreMark/MHz. They are designed for simple and intuitive migration with identical peripheral modules, hex compatible code, identical linear address map and pin compatible migration paths between all devices in the product series. All devices include intelligent and flexible peripherals, Event System for inter-peripheral signaling, and support for capacitive touch button, slider and wheel user interfaces. The SAM D21L microcontrollers provide the following features: In-system programmable Flash, twelve- channel direct memory access (DMA) controller, 12 channel Event System, programmable interrupt controller, up to 52 programmable I/O pins, 32-bit real-time clock and calendar, up to five 16-bit Timer/ Counters (TC) and three 24-bit Timer/Counters for Control (TCC), where each TC can be configured to perform frequency and waveform generation, accurate program execution timing or input capture with time and frequency measurement of digital signals. The TCs can operate in 8- or 16-bit mode, selected TCs can be cascaded to form a 32-bit TC, and three timer/counters have extended functions optimized for motor, lighting and other control applications. The series provide up to six Serial Communication Modules (SERCOM) that each can be configured to act as an USART, UART, SPI, I2C up to 3.4MHz, SMBus, PMBus, and LIN slave; up to eighteen-channel 350ksps 12-bit ADC with programmable gain and optional oversampling and decimation supporting up to 16-bit resolution, one 10-bit 350ksps DAC, four analog comparators with window mode; programmable Watchdog Timer, brown-out detector and power- on reset and two-pin Serial Wire Debug (SWD) program and debug interface. All devices have accurate and low-power external and internal oscillators. All oscillators can be used as a source for the system clock. Different clock domains can be independently configured to run at different frequencies, enabling power saving by running each peripheral at its optimal clock frequency, and thus maintaining a high CPU frequency while reducing power consumption. The SAM D21L microcontrollers have two software-selectable sleep modes, idle and standby. In idle mode the CPU is stopped while all other functions can be kept running. In standby all clocks and functions are stopped expect those selected to continue running. The device supports SleepWalking. This feature allows the peripheral to wake up from sleep based on predefined conditions, and thus allows the CPU to wake up only when needed, e.g. when a threshold is crossed or a result is ready. The Event System supports synchronous and asynchronous events, allowing peripherals to receive, react to and send events even in standby mode. The Flash program memory can be reprogrammed in-system through the SWD interface. The same interface can be used for non-intrusive on-chip debug of application code. A boot loader running in the device can use any communication interface to download and upgrade the application program in the Flash memory. The SAM D21L microcontrollers are supported with a full suite of program and system development tools, including C compilers, macro assemblers, program debugger/simulators, programmers and evaluation kits. © 2017 Microchip Technology Inc.
Datasheet Summary
40001885A-page 5 Document Outline Introduction Features Table of Contents 1. Description 2. Configuration Summary 3. Ordering Information 3.1. SAM D21ExL 3.2. SAM D21GxL 3.3. Device Identification 4. Block Diagram 5. Pinout 5.1. SAM D21GxL 5.1.1. QFN48 5.2. SAM D21ExL 5.2.1. QFN32 / TQFP32 6. Product Mapping 7. Processor And Architecture 7.1. Cortex M0+ Processor 7.1.1. Cortex M0+ Configuration 7.1.2. Cortex-M0+ Peripherals 7.1.3. Cortex-M0+ Address Map 7.1.4. I/O Interface 7.1.4.1. Overview 7.1.4.2. Description 7.2. Nested Vector Interrupt Controller 7.2.1. Overview 7.2.2. Interrupt Line Mapping 7.3. Micro Trace Buffer 7.3.1. Features 7.3.2. Overview 7.4. High-Speed Bus System 7.4.1. Features 7.4.2. Configuration 7.4.3. SRAM Quality of Service 7.5. AHB-APB Bridge 7.6. PAC - Peripheral Access Controller 7.6.1. Overview 7.6.2. Register Description 7.6.2.1. PAC0 Register Description 7.6.2.1.1. Write Protect Clear 7.6.2.1.2. Write Protect Set 7.6.2.2. PAC1 Register Description 7.6.2.2.1. Write Protect Clear 7.6.2.2.2. Write Protect Set 7.6.2.3. PAC2 Register Description 7.6.2.3.1. Write Protect Clear 7.6.2.3.2. Write Protect Set 8. Packaging Information 8.1. Thermal Considerations 8.1.1. Thermal Resistance Data 8.1.2. Junction Temperature 8.2. Package Drawings 8.2.1. 48 pin QFN 8.2.2. 32 pin TQFP 8.2.3. 32 pin QFN 8.3. Soldering Profile The Microchip Web Site Customer Change Notification Service Customer Support Product Identification System Microchip Devices Code Protection Feature Legal Notice Trademarks Quality Management System Certified by DNV Worldwide Sales and Service
The SAM D21L is a series of low-power microcontrollers using the 32-bit ARM® Cortex®-M0+ processor, and offered in 32- and 48-pin packages with up to 64KB Flash and 8KB of SRAM. The SAM D21L operate at a maximum frequency of 48MHz and reach 2.46 CoreMark/MHz. They are designed for simple and intuitive migration with identical peripheral modules, hex compatible code, identical linear address map and pin compatible migration paths between all devices in the product series. All devices include intelligent and flexible peripherals, Event System for inter-peripheral signaling, and support for capacitive touch button, slider and wheel user interfaces. The SAM D21L microcontrollers provide the following features: In-system programmable Flash, twelve- channel direct memory access (DMA) controller, 12 channel Event System, programmable interrupt controller, up to 52 programmable I/O pins, 32-bit real-time clock and calendar, up to five 16-bit Timer/ Counters (TC) and three 24-bit Timer/Counters for Control (TCC), where each TC can be configured to perform frequency and waveform generation, accurate program execution timing or input capture with time and frequency measurement of digital signals. The TCs can operate in 8- or 16-bit mode, selected TCs can be cascaded to form a 32-bit TC, and three timer/counters have extended functions optimized for motor, lighting and other control applications. The series provide up to six Serial Communication Modules (SERCOM) that each can be configured to act as an USART, UART, SPI, I2C up to 3.4MHz, SMBus, PMBus, and LIN slave; up to eighteen-channel 350ksps 12-bit ADC with programmable gain and optional oversampling and decimation supporting up to 16-bit resolution, one 10-bit 350ksps DAC, four analog comparators with window mode; programmable Watchdog Timer, brown-out detector and power- on reset and two-pin Serial Wire Debug (SWD) program and debug interface. All devices have accurate and low-power external and internal oscillators. All oscillators can be used as a source for the system clock. Different clock domains can be independently configured to run at different frequencies, enabling power saving by running each peripheral at its optimal clock frequency, and thus maintaining a high CPU frequency while reducing power consumption. The SAM D21L microcontrollers have two software-selectable sleep modes, idle and standby. In idle mode the CPU is stopped while all other functions can be kept running. In standby all clocks and functions are stopped expect those selected to continue running. The device supports SleepWalking. This feature allows the peripheral to wake up from sleep based on predefined conditions, and thus allows the CPU to wake up only when needed, e.g. when a threshold is crossed or a result is ready. The Event System supports synchronous and asynchronous events, allowing peripherals to receive, react to and send events even in standby mode. The Flash program memory can be reprogrammed in-system through the SWD interface. The same interface can be used for non-intrusive on-chip debug of application code. A boot loader running in the device can use any communication interface to download and upgrade the application program in the Flash memory. The SAM D21L microcontrollers are supported with a full suite of program and system development tools, including C compilers, macro assemblers, program debugger/simulators, programmers and evaluation kits. © 2017 Microchip Technology Inc.
Datasheet Summary
40001885A-page 5 Document Outline Introduction Features Table of Contents 1. Description 2. Configuration Summary 3. Ordering Information 3.1. SAM D21ExL 3.2. SAM D21GxL 3.3. Device Identification 4. Block Diagram 5. Pinout 5.1. SAM D21GxL 5.1.1. QFN48 5.2. SAM D21ExL 5.2.1. QFN32 / TQFP32 6. Product Mapping 7. Processor And Architecture 7.1. Cortex M0+ Processor 7.1.1. Cortex M0+ Configuration 7.1.2. Cortex-M0+ Peripherals 7.1.3. Cortex-M0+ Address Map 7.1.4. I/O Interface 7.1.4.1. Overview 7.1.4.2. Description 7.2. Nested Vector Interrupt Controller 7.2.1. Overview 7.2.2. Interrupt Line Mapping 7.3. Micro Trace Buffer 7.3.1. Features 7.3.2. Overview 7.4. High-Speed Bus System 7.4.1. Features 7.4.2. Configuration 7.4.3. SRAM Quality of Service 7.5. AHB-APB Bridge 7.6. PAC - Peripheral Access Controller 7.6.1. Overview 7.6.2. Register Description 7.6.2.1. PAC0 Register Description 7.6.2.1.1. Write Protect Clear 7.6.2.1.2. Write Protect Set 7.6.2.2. PAC1 Register Description 7.6.2.2.1. Write Protect Clear 7.6.2.2.2. Write Protect Set 7.6.2.3. PAC2 Register Description 7.6.2.3.1. Write Protect Clear 7.6.2.3.2. Write Protect Set 8. Packaging Information 8.1. Thermal Considerations 8.1.1. Thermal Resistance Data 8.1.2. Junction Temperature 8.2. Package Drawings 8.2.1. 48 pin QFN 8.2.2. 32 pin TQFP 8.2.3. 32 pin QFN 8.3. Soldering Profile The Microchip Web Site Customer Change Notification Service Customer Support Product Identification System Microchip Devices Code Protection Feature Legal Notice Trademarks Quality Management System Certified by DNV Worldwide Sales and Service
