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− | = Why the Arduino Due =
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− | This was my selection criteria:
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− | * Popular platform, well supported, reasonably priced.
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− | * Open-source hardware. <br/> Hopefully this will lead to lower prices and longer availability.
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− | * 32-bit CPU with good toolchain support.
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− | * High Speed (480 Mbps) USB tranfers (effective throughput up to 35 MB/s or 280 Mbit/s). <br/> This is about time, the USB 2.0 spec was released in April 2000 (!). <br/> Most ARM microcontrollers support only the 11 Mbit/s mode (as of 2013).
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− | Other candidates:
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− | * The Beagle Bone was mostly sold out at the time.
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− | * The Raspeberry Pi is designed to act as an USB Host, and not as an USB Device.
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− | = Specs =
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− | The Arduino Due has an AT91SAM3X8E microcontroller with the following features:
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− | * ARM Cortex-M3 core:
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− | ** Implements the ARMv7-M architecture, which is a 32-bit architecture.
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− | ** Supports all of the base Thumb-2 instruction set, where instructions can be 16-bit or 32-bit long.
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− | ** Supports only Thumb-2, does not support the original 32-bit ARM instruction set.
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− | ** Hardware multiplication and division.
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− | ** Memory Protection Unit with 8 regions.
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− | ** Limited support for unaligned memory accesses.
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− | ** Choice of several modes with different privilege levels (user, supervisor...).
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− | ** Support for single-bit atomic operations with (bit-banding)
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− | ** No floating point support.
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− | * 84 MHz clock frequency.
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− | * 2 x 256 KBytes Flash.
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− | * 64 + 32 KBytes RAM.
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− | * The "native" USB port and can do High Speed USB 2.0 (480 Mbit/s).
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− | * JTAG port
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− | = Inadequate as a learning and hacking platform =
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− | The Arduino Due is surprisingly inadequate as a learning and hacking platform:
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− | * It is relatively expensive compared to more powerful platforms like the Rasperry Pi, the Beagle Bone and many of the microcontroller evaluation boards. <br/> Due to the low availability 4 months after release date I ended up paying 59 € for it, and that hurts if you manage to fry it during your experiments.
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− | * The development environment has no integrated debugger (!).
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− | * Launching a program, however small, takes a few seconds. <br/> That is quite a long time for such a modern board, it goes on your nerves. Maybe it is due to the beta development environment version 1.5.2 I tested, but why is it still beta? The release date was 22nd October 2012, more than 4 months ago.
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− | * It can only interface at 3.3 V level. <br/> The Bus Pirate has a CD4066B analog switch that uses an external reference voltage. <br/> There are warnings all over the place that you can damage the board with a 5 V level, but why is there no protection circuitry? For hackers and learners such a safety feature would be a welcomed addition. How about some integrated 5 V capability too? With a small [http://en.wikipedia.org/wiki/Complex_programmable_logic_device CPLD] or [http://en.wikipedia.org/wiki/Field-programmable_gate_array FPGA] you could probably choose your voltage level on a pin basis.
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− | * The board has a single user LED and no user buttons whatsoever, let alone any kind of display or sound ability. <br/> You need extra hardware for the most simple of tests.
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− | * Serious hackers will need a [http://en.wikipedia.org/wiki/In-circuit_emulator JTAG-based hardware debugger], which costs at least 50 €. <br/> There are some cheap USB-Blaster clones for 10 € in Ebay, but I haven't been able to make mine work properly yet. <br/> The Arduino designers added a separate 8-bit AVR CPU in order to update the main microcontroller firmware over the "programming" USB port. What a complete waste of time! They could have added some existing JTAG-over-USB chip, or they could have made one themselves by connecting that little AVR to the JTAG wires.
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− | * The JTAG header is smaller than usual, it has a 1.27 mm raster instead of the normal 2.54 mm. <br/> Most hackers will have to pay extra for an adapter.
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− | = Connecting over JTAG =
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− | When connected to the Arduino Due, [http://openocd.sourceforge.net OpenOCD] discovers a [http://en.wikipedia.org/wiki/Joint_Test_Action_Group JTAG] IDCODE of 0x4BA00477. The JTAG Instruction Register has a length of 4 bits.
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− | The IDCODE breakdown, using [https://sourceforge.net/apps/mediawiki/filereadtest/index.php?title=DecodeJtagIdcode my script to decode JTAG IDCODEs], is as follows:
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− | Decoding of JTAG IDCODE 0x4BA00477 (1268778103, 0b01001011101000000000010001110111):
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− | Version: 0b0100 (0x4, 4)
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− | Part number: 0b1011101000000000 (0xBA00, 47616)
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− | Manufacturer: 0b01000111011 (0x23B, 571) # Name: ARM Ltd.
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− | Leading bit: 1 # Always set to 1 according to the IEEE standard 1149.1
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