This project aims at a wireless network with BLE nodes that use their mutual signal strengths to build up a network with their relative locations. This can be used later by someone carrying a smartphone to establish their location indoors. Everybody say that they can do it, but very few solutions are actually out there. Let's hope we can change that.

Bluetooth LE (BLE) does not inherently fit a wireless network. We have technology in-house (at the Almende group) that can do this Myrianed, but it has not been accepted in the mainstream yet. By the way, it is my personal opinion that solutions such as ZigBee, Z-Wave, MyriaNed, and other mesh solutions, will remain marginal except if they get accepted in a common handheld.

That's why BLE is interesting. A lot of phones come with BLE, so a solution is automatically useful to a large variety of people. It is not the best technology for the job. The network topology is a Personal Area Network (PAN), not a Local Area Network (LAN). This means that you cannot have all nodes communicating with all other nodes at the same time. To get RSSI values we will have to set up connections to other nodes and tear them down again. Not very efficient. But it will do the job.

However, through the Timeslot API, it is possible to run a totally different protocol parallel to BLE using the same radio. This means that we can have a mesh network at the same time as providing for BLE functionality. The new S130 SoftDevice adds to that even multiple BLE roles at the same time. So many possibilities arise!

Feel free to clone this repos.

The code base comes from http://hg.cmason.com/nrf. Thanks a lot Christopher!

The installation should not be hard when you have the Nordic SDK. Get this from their website after buying a development kit. You also need a cross-compiler for ARM. You need the JLink utilities from Segger. And you need cmake for the build process.

• Nordic nRF51822 SDK
• Nordic S110 Softdevice
• JLink Software, there is a .deb file
• sudo aptitude install cmake

A cross-compiler for ARM is the GCC cross-compiler which is maintained by the ARM folks on Launchpad.

curl -v -O https://launchpad.net/gcc-arm-embedded/4.8/4.8-2014-q3-update/+download/gcc-arm-none-eabi-4_8-2014q3-20140805-linux.tar.bz2
tar -xvf gcc-arm-none-eabi-4_8-2014q3-20140805-linux.tar.bz2 -C /opt

This is a 32-bit application, so you will need some dependencies:

sudo apt-get install libstdc++6:i386 libncurses5:i386

If the cross-compiler does not work, make sure you check if all its dependencies are met:

ldd /opt/gcc-arm-none-eabi-4_8-2014q3/bin/arm-none-eabi-gcc

Unpack the Nordic files to for example the /opt/softdevices and /opt/nrf51_sdk directories.

It is a cmake build system, so you will need it:

sudo apt-get install cmake

You can now just type make in the main directory. Or you can build using the scripts (see below). Before that you'll have to adjust the default configuration settings (see below as well).

There is a bug in one of the SDK files, namely nrf_svc.h (different location depending on the SDK version):

/opt/nrf51_sdk/v6/nrf51822/Include/s110/nrf_svc.h
/opt/nrf51_sdk/v4/nrf51822/Include/ble/softdevice/nrf_svc.h

Change the assembly line:

    "bx r14" : : "I" (number) : "r0" \

Into:

    "bx r14" : : "I" ((uint16_t)number) : "r0" \

You will have to attach a programmer/debugger somehow. Towards that you only need four pins. On the RFduino this is GND, 3V, RESET, and FACTORY and they are subsequent pins on that side of the RFduino where there are most pins (the other side has the antenna stealing a bit of space for eventual pins). The pin layout of the JLink connector is written out on the DoBots blog.

Fork the code by clicking on:

• Fork https://github.com/dobots/bluenet/fork.
• git clone https://github.com/${YOUR_GITHUB_USERNAME}/bluenet
• let us call this directory $BLUENET

Now you will have to set all fields in the configuration file:

• cp CMakeBuild.config.default CMakeBuild.config
• adjust the NRF51822_DIR to wherever you installed the Nordic SDK (it should have /Include and /Source subdirectories
• adjust the SOFTDEVICE_DIR to wherever you unzipped the latest SoftDevice from Nordic
• adjust the SOFTDEVICE_SERIES to for example 110 or 130 (SoftDevice name starts with it, without the s)
• adjust major accordingly SOFTDEVICE_MAJOR=7
• adjust minor accordingly SOFTDEVICE_MINOR=0
• adjust the SOFTDEVICE_DIR_API to the directory with the SoftDevice include files
• set SOFTDEVICE_NO_SEPARATE_UICR_SECTION=1 if you use one of the earlier s110 softdevices with a separate UICR section
• adjust the type SOFTDEVICE accordingly (basename of file without _softdevice.hex)
• set the APPLICATION_START_ADDRESS to start of application in FLASH (called CODE_R1_BASE in Nordic documentation)
• set the APPLICATION_LENGTH to what remains of FLASH
• set RAM_R1_BASE to the start of RAM that is available (SoftDevice S130 v0.5 uses a staggering 10kB from the 16kB!)
• set RAM_APPLICATION_AMOUNT to what remains for the application in RAM
• adjust the COMPILER_PATH and COMPILER_TYPE to your compiler (it will be used as $COMPILER_PATH\bin\$COMPILER_TYPE-gcc)
• adjust JLINK to the full name of the JLink utility (JLinkExe on Linux)
• adjust JLINK_GDB_SERVER to the full name of the JLink utility that supports gdb (JLinkGDBServer on Linux)
• set BLUETOOTH_NAME to something you like, but make sure it's short.
• adjust INDOOR_SERVICE to 1 if you want to enable it, the same is true for the other services
• adjust CHAR_MESHING to 1 if you want to enable meshing functionality, the same is true for other characteristics
• adjust BOARD to the correct number for your board. This determines the pin layout.
• adjust HARDWARE_VERSION to the correct version of the NRF51 chip you have. Use script/hardware_version.sh to check your version.
• adjust SERIAL_VERBOSITY to the value you prefer. Set it to None to disable all logging over serial. The default is 1 (info).
• adjust MASTER_BUFFER_SIZE if you want to have a larger buffer (this buffer is reused by all characteristics that use more than a single byte or string)

Let us now install the SoftDevice on the nRF51822:

cd scripts
./softdevice.sh build
./softdevice.sh upload

Now we can build our own software:

cd $BLUENET
make

Alternatively, you can build it using our script:

cd scripts
./firmware.sh build crownstone

There is also an upload and debug script. The first uses JLink to upload, the second uses gdb to attach itself to the running process:

./firmware.sh upload crownstone
./firmware.sh debug crownstone

You can also run everything in sequence:

./firmware.sh all crownstone

And there you go. There are some more utility scripts, such as reboot.sh. Use as you wish.

The above assumes you have the J-Link programmer from Nordic. If you do not have that device, you can still program something like the RFduino or the Crownstone, by using an ST-Link. A full explanation can be found on https://dobots.nl/2015/01/23/programming-the-nrf51822-with-the-st-link/.

First of all you should combine all the required binaries into one big binary. This is done by the script combine.sh. Before you use it, you will need to install srec_cat on your system.

sudo apt-get install srecord

If you call the script it basically just runs srec_cat:

./combine.sh

And you will see that it runs something like this:

srec_cat /opt/softdevices/s110_nrf51822_7.0.0_softdevice.hex -intel crownstone.bin -binary -offset 0x00016000 -o combined.hex -intel

You have to adjust that file on the moment manually to switch between softdevices or to add/remove the bootloader, sorry! Note that the result is a .hex file. Such a file does haveinformation across multiple memory sections. If you upload a .bin file often configuration bits/bytes will not be set!

Rather than downloading openocd from the Ubuntu repositories, it is recommended to get the newest software from the source:

cd /opt
git clone https://github.com/ntfreak/openocd
sudo aptitude install libtool automake libusb-1.0-0-dev expect
cd openocd
./bootstrap
./configure --enable-stlink
make
sudo make install

Also, make sure you can use the USB ST-Link device without sudo rights:

sudo cp scripts/openocd/49-stlinkv2.rules /etc/udev/rules.d
sudo restart udev

You can now use the flash_openocd.sh script in the scripts directory:

./flash_openocd.sh init

And in another console:

./flash_openocd.sh upload combined.bin

Here the binary combined.bin is the softdevice and application combined.

The meshion functionality is the one we are currently integrating on the moment. So, this is a moving target. Set CHAR_MESHING to 0 if you don't need it.

For the meshing functionality we use https://github.com/NordicSemiconductor/nRF51-ble-bcast-mesh written by a Trond Einar Snekvik, department of Engineering Cybernetics at Norwegian University of Science and Technology (and Nordic Semiconductors). This code makes use of the Timeslot API which is not supported yet in the alpha versions of the S130. Hence, if you want to use the meshing functionality, you will have to use the S110.

This means that if you want to use a bootloader, you will also need the S110 version of it, and the same is true for the upload script:

• https://github.com/dobots/nrf51-dfu-bootloader-for-gcc-compiler/tree/s110
• https://github.com/dobots/nrf51_dfu_linux

Currently UART for debugging. In case you happen to have the nRFgo Motherboard (nRF6310, strongly recommended) you can easily connect the pints at P2.0 and P2.1 to respectively the pins RXD and TXD on P15 on the board. Do not forget to switch on the RS232 switch. Subsequently you will need some RS232 to USB cable if you haven't an extremely old laptop. The current set baudrate you can find in src/serial.cpp and is 38400 baud. To read from serial, my personal favorite application is minicom, but feel free to use any other program.

(sudo) minicom -c on -s -D /dev/ttyUSB0

The sudo rights are only necessary if your udev rights are not properly set. The above flags just set colors to on and define the right usb port to use (if you've multiple).

To upload a new program when the Crownstone is embedded in a wall socket is cumbersome. For that reason for deployment we recommend to add a bootloader. The default bootloader from Nordic does not work with the S130 devices. You will need our fork:

git clone https://github.com/dobots/nrf51-dfu-bootloader-for-gcc-compiler
cd scripts
./all.sh

Note, that if you want to use meshing you will need the S110 version! This can be found in the s110 tag (see also above).

You will have to set some fields such that the bootloader is loaded rather than the application directly. If you use the J-Link this is the sequence of commands you will need:

./softdevice.sh all
./writebyte.sh 0x10001014 0x00034000
./firmware.sh all bootloader 0x00034000

Here we place the bootloader at position 0x00034000. If the bootloader becomes larger in size, you will need to go down and adjust the code in the dfu_types.h file in the bootloader code.

And you should be good to upload binaries, for example with the following python script:

git clone https://github.com/dobots/nrf51_dfu_linux
python dfu.py -f crownstone.hex -a CD:E3:4A:47:1C:E4

Currently the upload script needs to be changed depending on the SoftDevice used, for the S130:

ctrlpt_handle = 0x10
ctrlpt_cccd_handle = 0x11
data_handle = 0x0E

And for the S110:

ctrlpt_handle = 0x0D
ctrlpt_cccd_handle = 0x0E
data_handle = 0x0B

Of course, this is too cumbersome. We will soon implement something that figures out the right handles automatically.

Make sure the bootloader is actually loaded and the proper address for the application is set. If you use the J-Link you can use ./general_command.sh to read individual memory locations:

mem 0x10001014 4

This should be 0x34000 if you use the bootloader. If it is 0xFFFF the application will be loaded from the application start address.

If the bootloader does not find a valid app, there might indeed not be an app available, o its configuration field that tells it that the app is correct isn't set properly:

mem 3FC00 10

This should return 0000 0001 0000 0000 0000 00FE 0000 0000. If it isn't set correctly, make sure you have uploaded the bootloader.hex file (and not only the bootloader.bin file).

There is iBeacon functionality, if you want to try that out. For that you will need to set a define in the main file.

#define IBEACON

This is not the normal operation mode of the Crownstones, and it is not guaranteed to stay.

• Clean up code
• Obtain RSSI values
• Set up management for establishing connections, getting RSSI values, and tear down connections again
• Create an algorithm to come up with all locations of the nodes. These positions are relative, not absolute. The network will be known up to rotation and scale.
• Implement this algorithm in a distributed fashion. The type of algorithm I have in mind is belief propagation / message passing.

Due to the fact that the SoftDevice S130 uses 10kB out of 16kB, we have to be really careful with the 6kB we have left. In the util/memory directory you can see a tool from Eliot Stock to visualize the foot print of functions. We removed for example exception handling.

Tips to reduce memory usage are really welcome!

This code is used in a commercial product at DoBots, the Crownstone. Our intellectual property exists on two levels. First, you can license our technology to create these extremely cheap BLE building blocks yourself. Second, we build services around BLE-enabled devices. This ranges from smartphones to gadgets such as the "virtual memo". What this means for you as a developer is that we can be transparent about the software on the Crownstone, which is why this repository exists. Feel free to build your own services on top of it, and benefit from our software development as much as you want.

It would be much appreciated to state "DoBots inside" in which case we will be happy to provide support to your organisation.

If you want to buy our hardware, please navigate to our website. We offer a hardware development kit for professional use.

The different other software tools and online resources have been mentioned above, but here is a short list:

• Bluenet (this repos)
• Bluenet documentation
• Bluenet documentation branch
• Bootloader
• DFU upload tool
• Crownstone website
• Crownstone Android app
• Crownstone app source
• Crownstone USB image
• Crownstone SDK manual

If you have any problems that are not solved by documentation, please ask them as a GitHub issue. In that case everybody can profit from things that are currently incorrectly formulated, not yet formulated, or need some other attention from us developers.

Obviously, the copyrights of the code written by Christopher, belong to him.

The copyrights (2014-2015) for the rest of the code belongs to the team of Distributed Organisms B.V. and are provided under an noncontagious open-source license:

• Authors: Anne van Rossum, Dominik Egger, Bart van Vliet
• Date: 27 Jan. 2014
• License: LGPL v3+, Apache, or MIT, your choice
• Almende B.V., http://www.almende.com and DoBots B.V., http://www.dobots.nl
• Rotterdam, The Netherlands

Note, that we do not use any header files from Nordic. The header files are rewritten from scratch by Christopher especially for that purpose. This means you are not finding a Nordic license text in this repository. Of course, this means that you will have to get those files from Nordic via different means (we recommend to buy the development kit). We just didn't want to "contaminate" this repository with files that we don't understand the license implications of.

The only exception is the code for the meshing functionality that is put online by Nordic itself on https://github.com/NordicSemiconductor/nRF51-ble-bcast-mesh. This functionality can be found in src/protocol and include/protocol/ and falls of course under the Nordic license. You can disable the meshing functionality with CHAR_MESHING=0 if you do want to exclude that code from becoming part of the binary. You can still use the services for individual nodes, but they won't be able to communicate with each other in that case.