Metadata-Version: 2.1
Name: uvicmuse
Version: 5.3.0
Summary: Stream and visualize EEG data from the Muse headset.
Home-page: UNKNOWN
Author: Bardia Barabadi
Author-email: bardiabarabadi@uvic.ca
License: MIT
Keywords: muse lsl eeg ble neuroscience matlab UDP
Platform: UNKNOWN
Classifier: Development Status :: 4 - Beta
Classifier: Intended Audience :: Science/Research
Classifier: Topic :: Software Development
Classifier: Operating System :: Microsoft :: Windows
Classifier: Operating System :: POSIX
Classifier: Operating System :: Unix
Classifier: Operating System :: MacOS
Classifier: Programming Language :: Python
Description-Content-Type: text/markdown
Requires-Dist: bitstring
Requires-Dist: pygatt
Requires-Dist: pandas
Requires-Dist: numpy
Requires-Dist: seaborn
Requires-Dist: pexpect
Requires-Dist: pillow
Requires-Dist: bleak
Requires-Dist: kivy (==2.0.0rc4)
Requires-Dist: docutils
Requires-Dist: pygments
Requires-Dist: pyserial
Requires-Dist: esptool
Requires-Dist: nest-asyncio
Requires-Dist: pylsl (==1.10.5)
Requires-Dist: pypiwin32 ; platform_system == "Windows"
Requires-Dist: kivy.deps.glew ; platform_system == "Windows"
Requires-Dist: kivy.deps.sdl2 ; platform_system == "Windows"
Requires-Dist: kivy.deps.gstreamer ; platform_system == "Windows"


# UVic MUSE

An application for streaming from MUSE headsets to MATLAB and other 
platforms. 

## Software Requirements

The code relies on [bleak](https://github.com/hbldh/bleak) (macOS) and [pygatt](https://github.com/peplin/pygatt) (Windows & Linux) for BLE communication 
and [pylsl](https://github.com/chkothe/pylsl) for LSL streaming. We highly recommend installing on a virtual environment (VE). You can build and manage those VEs using [Anaconda](https://www.anaconda.com/), 
the instructions to install and setup a conda environment is described [here](https://docs.anaconda.com/anaconda/install/).

**Compatible with Python 3.8+**

_Note: if you run into any issues, first check out out Common Issues
and then the Issues section of [this](https://github.com/bardiabarabadi/uvicMUSE) repository_

## Hardware Requirements

** Compatible with MUSE _MU-02_ and _MU-03_

##### MacOS:
This app uses the built-in bluetooth hardware to communicate with MUSE. No extra hardware is required.

##### Windows & Linux:
UVic MUSE requires an USB dongle (use [BLED112](http://www.farnell.com/datasheets/2674198.pdf?_ga=2.79024144.587051681.1584504877-1039421750.1584504877&_gac=1.255907449.1584504893.Cj0KCQjw6sHzBRCbARIsAF8FMpWVas72rjYW8HkIbpjfUe97CBonZR71Yi22iGbSvDSER9rcJJ1JbqsaAit0EALw_wcB) 
for the best results) to communicate with MUSE on windows and Linux. **Make sure you install the correct version.**

## Getting Started

To stream from MUSE to MATLAB ro other platforms, a _Streamer_ application is required. 
Transmitted data from _Streamer_ side then can be received and used by the _Receiver_ application. 
Take a look at this chart below:


![Top](image-01.png)

This project has two sections, first, *UVic MUSE* that connects to MUSE 
over Bluetooth and streams its data over UDP and LSL.
Second, a MATLAB toolbox (and `MuseUdp.m`) that allows the user to receive 
*UVic MUSE* transmitted data over UDP protocol. 
In the following sections we go through installation and usage of *UVic MUSE*
and then explain about part two, MuseUdp.   

### UVic MUSE Installation

On Windows we suggest the user to install Anaconda and run all of the following commands
(including optional commands) in an Anaconda Prompt. You may need to install
 [Microsoft Visual C++ Build Tools](https://visualstudio.microsoft.com/downloads/#build-tools-for-visual-studio-2017) (~1GB) from microsoft website if you don't use Anaconda.

On MacOS and linux, install Anaconda (or miniconda), 
open a terminal, and follow these commands:

**If you don't want to use a virtual environment, use Terminal (Linux and OSx) 
or Command Prompt (Windows) and skip the optional steps.**

(optional) Create a new conda environment.

    conda create --name muse_env python=3.8

(optional) Activate conda environment

    conda activate muse_env

Install dependencies

    pip install pylsl pygatt # For Windows and MacOS
    pip install pylsl==1.10.5 pygatt # For Linux


Install UVicMUSE using `pip`

    pip install --force-reinstall uvicmuse==3.3.0 # for Windows & Linux (with dongle)
    pip install --force-reinstall uvicmuse==5.3.0 # for macOS (built-in bluetooth)


#### Running UVicMUSE:

To run and use *UVic MUSE* open a Terminal (Linux & OSx) or Command Prompt (Windows)
and type in the commands below:

(optional) Activate the virtual environment

    conda activate muse_env

Run UVicMUSE:

    uvicmuse

**If you manage to install UVicMUSE without conda in Windows, you can run it by opening the start menu
and typing uvicmuse**

#### GUI: 

![Top](uvicmuse_.png)

#### Streaming Procedure:
Follow steps shown below to stream the MUSE sensory data. Remember to correctly specify the **Required Entries** variables
before moving on to the next step. 

- Search to get a list of available MUSEs
- Connect to one of the MUSEs. **Required Entries** = Checkboxes (UDP, LSL, EEG, PPG, ACC, GYRO) 
- Start Streaming over UDP and LSL (if enabled). **Required Entries** = Filters (Highpass, Lowpass, Notch)

Notes:
* Stopping the stream won't disconnect the MUSE (use this feature for changing filters configurations)
* Search is required after disconnecting from a MUSE 
* There is no need to set checkboxes on macOS, all sensors are active by default

## Receiver Toolbox (MuseUdp)

In this section we explain the methods available in the MATLAB toolbox. The main responsibility of a receiver
is to connect to UDP socket (same socket as UVic MUSE) and receive data that is being transmitted from MUSE device.

#### MATLAB Toolbox

Download [MuseUdp Toolbox](https://www.mathworks.com/matlabcentral/fileexchange/74583-museudp) from MATLAB file exchange. 
Open and install the toolbox on MATLAB. Moreover, you need to install [Instrument Control Toolbox](https://www.mathworks.com/products/instrument.html)
 to establish UDP connections.

To see all of the available methods (functions), create an object from MuseUdp and call methods for it:

    mu = MuseUdp();
    methods(mu);

To get a single sample from UVic MUSE use:

    mu = MuseUdp();
    [data, timestamp, success] = mu.get_xxx_sample()

Replace `xxx`with `eeg`, `ppg`, `acc` or `gyro`. The sampled data may have different size according to `xxx`, `eeg` has 5 
channels per sample, the rest of the sensors return 3 channels data. 

To read sampled data in chunks, you need to specify the chunk size and call `mu.get_xxx_chunk(###)`, replace `xxx` with sensor type
and `###` with the chunk size. The output size, `size(data)`, will be `[chunk_size, 5]` for `eeg` and `[chunk_size, 3]` for others. 

*Note: since the buffer size is limited for UDP protocols, each sample of `eeg` contains four bytes for timestamp and
4 * 5 = 20 bytes for data (24B total). Since default buffer size in UDP is 1kB, one cannot get a chunk larger that 40 samples.
We suggest using multiple instances of `get_xxx_chunk()`, but you can change the buffer size by calling the function below:

    mu.set_udp_buffer_size(2048) % 2kB buffer

## Pyhton Library
 If you wan to use MUSE's sensory data in python, you can use uvicmuse as a python library. Here is how it works:

 First you need to import the `MuseWrapper` class into your code. Also, you will going to need the `asyncio` library.

    from uvicmuse.MuseWrapper import MuseWrapper as MW
    import asyncio
 Now get the event loop using the `get_even_loop` method and pass it to the `MuseWrapper`.

    loop = asyncio.get_event_loop()
    M_wrapper = MW (loop = loop,
                    target_name = None,
                    timeout = 10,
                    max_buff_len = 500) 
 Let's take a look at all of the entries of the `MuseWrapper`:

 **Loop**: The event loop, use get_event_loop to acquire

 **target_name**: (optional) Use if you want to connect to a specific device. You can use `"Muse-3BEA"` or `"3BEA"`. Leave this input empty (or `None`) if there is only one device in range. You will get an error if there are more than one devices available and this input is empty.

 **timeout**: (optional) The timeout for the search. May need to be increase according to the BT device and/or the BT traffic. 

 **max_buff_size**: (optional) The maximum number of samples that to be temporary saved in the internal buffer. Default is 512.

The next step is to search for the target MUSE and connect to it:

    M_wrapper.search_and_connect() # returnes True if the connection is successful

Finally you can go ahead and read samples from the MUSE:

    EEG_data = M_wrapper.pull_eeg()
    PPG_data = M_wrapper.pull_ppg() # Not available in MU-02
    ACC_data = M_wrapper.pull_acc()
    GYRO_data = M_wrapper.pull_gyro()

The output is a list of samples each containing 5 (for EEG) or 3 (for others) values followed by a timestamp. The buffers reset automatically when read.

To disconnect the MUSE, use:

    M_wrapper.disconnect()

## Issues

On MacOSx: Application crashes after running:

    pip uninstall serial pyserial
    conda uninstall serial pyserial
    pip install pyserial esptool

## Citing UVicMUSE

```
@misc{UVicMUSE,
  author       = {Bardia Barabadi},
  title        = {uvic-muse},
  month        = March,
  year         = 2020,
}
```

