AVR601: Atmel Modular Evaluation Kits for Motor Control Applications
8-bit
1. Introduction
Following the success of the MC100 and MC200 motor control demonstration kits, Atmel is expanding the support for motor control applications and presents a new modular concept for Motor Control evaluation kits. As shown on figure 1, each motor application is now supported by two or three evaluation boards: • A power board providing the high current to the motor • A processor board supporting one AVR microcontroller and the user interface • An optional interface board which may be physically inserted between the Power Board and the Processor Board for signal conditioning. Figure 1-1. System Architecture B1 8 Processor Board B2 8 B3 ATtiny861 ATMega32M ATXmega ... 8 B4 8/16 (Optional for Specific Purpose) Interface Board A1 8 Power Board A2 8 A3 8 A4 8/16 MOSFETs SPM
Microcontrollers
Application Note
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The offering includes one low voltage power board, three processor boards and the associated firmware. These four boards as shown on figure 2: • MC300 is the low voltage power board (max 40V). • MC301 is the processor board with the low cost ATtinyx61 • MC303 is the processor board with the new high performance XMEGA™ • MC310 is the processor board with the ATMega32M1 (with CAN interface) • More processor boards will become available in the future
Figure 1-2.
Motor control Boards offering MC303
MC301
MC300 MC310
The Atmel Motor Control Interface bus (AMCI bus) shown on Figure 1-3, allows the communication between the power board and the processor board; most motor types are supported by this interface: • BLDC and BLAC motors • AC induction motors • Switch reluctance motors • Stepper motors The AMCI bus uses three 8 bit connectors and one 8/16 bit connector. The interface supports up to four phases (U, V, W, X), each with half bridge control and both voltage and current feedback. With three phase motors, the free X channel can be used for a brake function. The interface also supports Hall sensors, speed, temperature and fault signals and also allows the control of the PFC (Power Factor Correction) from the CPU board. All signals are logic signals or analog signals scaled to reach the digital Vcc.
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Figure 1-3. AMCI Motor Control bus
This bus can be used by any AVR microcontroller to control a motor. This is an ideal interface to optimize the system cost and to identify the cheapest solution with the required level of performance.
2. Processor boards
As shown on Figure 5, each processor board has similar architecture and features; it includes: • The corresponding AVR processor, which handles the motor control application and the other tasks. • A USB interface for communication with the host using Atmel Motor Control PC software. The USB bridge is handled by an AT90USB1287. • A connector to plug in an optional ATAVRDB101 display and Human Machine Interface board. • A potentiometer for providing analog speed target to the controller. • Programming and debugging connectors. • The four AMCI Motor Control bus connectors.
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Figure 2-1.
Processor board placement
The MC301 supports the ATTinyx61 family of low cost AVR dedicated to motor control. It can also handle analog, TWI or SPI speed reference for rotational speed control.
The MC303 supports the XMEGA™ family of high performance devices that can handle various functions while the CPU handles motor control intensive algorithm. MC303 with DB101 top module is shown on figure 6.
The MC310 board supports the ATMega32M1, a cost efficient device providing CAN and LIN communications in automotive and industrial designs. The board includes additional connectors for several communication interfaces: • CAN • LIN • RS232
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Figure 2-2. MC303 with DB101 display and HMI top module
3. MC300 low voltage power interface
This board, shown on figure 7, is intended to drive low voltage, medium power motors with following specifications: • Voltage from 10 to 40 VDC. • Current up to 6 Amperes (continuous load) The power board supplies the processor board. The board provides interface for Hall sensors or back EMF information to run sensorless control of the motor. The MC300, mainly targeted to drive BLDC and BLAC motors, can also be used with other motors types like stepper motors.
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Figure 3-1.
MC300 board with BLDC motor
4. Firmware package
The flexibility of the modular hardware approach is supported by a growing software package. BLDC and BLAC motors with sensor control are fully supported. Sensorless control is also supported. Please refer to Atmel web site notes and code examples.
www.atmel.com/motorcontrol for availability of application
Even if a specific combination of microcontroller, driver stage and motor type might not be available from at the release, the similarity in fundamental functionality motors means that it is an option to extract relevant parts of the existing code examples, and modify and reuse it in other implementations.
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5. Availability & Ordering codes
To simplify the order entry, complete evaluation kits are also available: MC320 includes the MC310 processor board, the MC300 power board and a small BLDC motor (see figure 8) MC321 includes the MC301 processor board , the MC300 power board and a small BLDC motor MC323 includes the MC303 processor board , the MC300 power board and a small BLDC motor
Figure 5-1.
MC320 Evaluation kit
MC300, 301, 303, 310, 320, 321 and 323 have the following ordering codes: • ATAVRMC300 • ATAVRMC301 • ATAVRMC303 • ATAVRMC310 • ATAVRMC320 (includes MC300, MC310, 12V BLDC motor and USB cable) • ATAVRMC321 (includes MC300, MC301, 12V BLDC motor and USB cable) • ATAVRMC323 (includes MC300, MC303, 12V BLDC motor and USB cable) The ATAVRDB101 display and Human Machine Interface add on board is also available.
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Documentation available: AVR430 - MC300 Hardware User’s Guide AVR469 – MC301 Hardware User’s Guide AVR470 – MC310 Hardware User’s Guide AVR194 Brushless DC Motor Control using Atmega32M1 Other documentation available: • AVR435: BLDC/BLAC Motor Control Using a Sinus Modulated PWM Algorithm • AVR440: Sensorless Control of Two-Phase Brushless DC Motor • AVR441: Intelligent BLDC Fan Controller with Temperature Sensor and Serial Interface • AVR442: BLDC Fan Motor Control with ATtiny13 • AVR443: Sensor-based control of three phase Brushless DC motor • AVR444: Sensorless control of 3-phase brushless DC motors • AVR446: Linear speed control of stepper motor • AVR447: Sinusoidal driving of three-phase permanent magnet motor using ATmega48/88/168 • AVR448: Control of High Voltage Three-phase BLDC Motor • AVR449: Sinusoidal driving of 3-phase permanent magnet motor using ATtiny261/461/861 • AVR452: Sensor-based Control of Three Phase Brushless DC Motors Using AT90CAN128/64/32 • AVR492: Brushless DC Motor control using AT90PWM3 • AVR493: Sensorless Commutation of Brushless DC Motor (BLDC) using AT90PWM3 and ATAVRMC100 • AVR494: AC Induction Motor Control Using the constant V/f Principle and a Natural PWM Algorithm • AVR495: AC Induction Motor Control Using the Constant V/f Principle and a Space-vector PWM Algorithm • Refer to www.atmel.com for the complete and updated list.
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