OpenBCI Program: BCI Controlled Exoskeleton

There are currently more than 1 billion people worldwide who are disabled and from that 15 million individuals are paralysed. Paralyzed individuals are often told they may never regain mobility, and with no new innovative solutions, they are left unable to do the most simple tasks such as walking, making them reliant on caregivers. 

Paralysis comes in different forms listed below:

• Monoplegia – Affects one arm or leg
• Hemiplegia – Affects one side of the body, including an arm and leg
• Paraplegia – Affects both legs
• Quadriplegia – Affects both arms and legs

BCI Exoskelaton is a prosthetic system designed to improve the lives of individuals with limb loss and those with limited motor functions, such as those affected by conditions like cerebral palsy or muscular dystrophy.

1. What are you making?

I’m developing a brain-controlled exoskeleton arm designed to help people who have difficulty moving their arms, such as individuals with paralysis, regain control over their movements. This device works by using a headset that detects brain signals, which are then processed and translated into specific actions for the exoskeleton. Essentially, the person thinks about moving their arm, and the exoskeleton interprets these thoughts, activating motors and joints in the arm to mimic natural movement.

The exoskeleton isn’t a permanent replacement for an arm but acts as an assistive device, offering support and helping the user perform everyday tasks more independently—like picking up a glass of water or holding a pen. My goal is to make this technology more affordable, durable, and easy to use compared to existing options, which are often costly and less accessible. By creating a more adaptable exoskeleton, I hope to give people the freedom to regain mobility in their arms without needing extensive surgeries or expensive equipment, empowering them to lead more active, independent lives.

2. How are OpenBCI tools being applied?

The technology provided by OpenBCI will be utilized in monitoring brain signals which will later be used to send controls to the exoskeleton. By using the Biosensing Bundle, I can take on this project in multiple ways, since I have different types of hardware and software tools. Below, I wrote the use applications of every item provided by OpenBCI.

Cyton + Daisy Biosensing Board

• Since this board can read up to 16 channels I will use the following channels to detect movement-related potentials (MRPs): F3, F4, C3, C4, P3, P4, O1, O2, T3, T4, Fp1, and Fp2.
• This board also provides really high-resolution brainwave signals, which allows me to conduct a detailed analysis of the electrical activity in different brain regions to maximize accuracy when connected with the Mark IV EEG Headset.

 Ultracortex Mark IV EEG Headset

• This headset is compatible with the Cyton + Daisy Biosensing Board which provides 16-channel high-quality brain signal readings. 
• Flexibility in sizes and an increase in comfort will support users who may be unfamiliar with EEG technology. 
• I am choosing the preassembled version as I don’t have access to a 3D printer and this will ensure the headset is correctly assembled. Furthermore, it allows me to spend more time on the construction of the project as a whole.

 EEG Headband Kit:

• I would use this kit when setting up the whole headset would be impractical, this would increase my overall efficiency towards the completion of the project. 
• The small, flexible design also makes it easier to apply in situations where a full headset could be cumbersome, like during initial trials or prototyping. 

Gold Cup Electrodes: 

• These electrodes will be used in conjunction with the EEG headset to ensure high-quality contact with the scalp for accurate EEG readings. They are critical for minimizing noise thus improving signal clarity.

EMG/ECG Snap Gel Electrodes + Pack:

• These electrodes will be used to monitor muscle activity (EMG) and heart signals (ECG). EMG data can help correlate physical movements with brain activity, while ECG data can provide insights into the user’s emotional state.

Dry EEG Comb Electrode:

• Increases the convenience of use to collect data
• May improve data collection efficiency, making it easier to gather data in various settings, including outdoor experiments or public demonstrations.

Pulse Sensor (Heart-Rate Monitor):

• Monitoring the heart rate in the project can be correlated with brain activity to see how emotional states and physical exertion may affect brain signals.

3. Why is this important?

This project is important because it addresses a real need for people who have lost arm mobility or strength, helping them regain independence in their daily lives. By creating an exoskeleton arm that can be controlled through brain signals, I’m making a project as an extension of the body, allowing people to move and interact with their environment just by thinking.

4. Who is involved in this project?

Currently, the project consists of me although I plan to work with others during the project as well. If you guys want to work together, reach out to me!

5. Want to learn more about this project?

To learn more about this project, you can visit my LinkedIn or Medium page for constant updates on the project. I post regular updates on the project every other month, and you can also reach out to my LinkedIn if you have any questions!

LinkedIn: https://www.linkedin.com/in/aarav-sharma-/

Medium: https://medium.com/@aaravsharma23

Email: [email protected]

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Updated Progress as of Feb 5th, 2025

When I first received the headset, I started to modify it(since it was open source) so that all 16 electrodes were focused on either the Frontal Lobe, Motor Cortex, or Motor Strip(part of the Motor Cortex).

The electrodes are specifically at the following points in the 10-20 System: Fp1, Fp2, AF3, AF4, AFz, F3, F4, FC3, FCz, FC4, C3, C1, CZ, C2, C4, and CPz. I 3D printed these modifications so that the electrodes could fit in the gaps of the headset. 

Check out an image of the headset after placing the modifications:

INSERT IMAGE

First, I wanted to do a small project to learn how to use the BrainFlow API with libraries like Matplotlib. I started by plotting EEG signals in Matplotlib and then set a threshold to detect eye blinks (using a simple equation: y = C, where C is the threshold value). My mini-project involved making a character jump whenever I blinked. This project excited me and helped me see the real potential of BCI technology and its practical applications. After that, I moved on to working on my main project…

After finishing the mini-project, I began developing the exoskeleton arm for my final project. The exoskeleton needs to have five controllable fingers, so I decided to thread a thick string through each finger. Later, these strings will be controlled by an MG995R positional servo motor, using a Tendon-Driven Actuation System.

Before I started to even think about the controls of the arm, I needed to work on the physical design of it. I started creating the robotic arm by 3D printing all the required components. This meant designing it in CAD(Fusion 360) and printing it on a printer(Adventurer 5M Pro). The arm was modified such that it included the exact measurements of my own fingers and arm.

Upon completing the 3D printing aspect of the project, I was required to assemble the hand. This required a lot of UHU Adhesive Glue! After this stage, I worked on threading the strings through all the holes, making sure it was correctly placed and that it would cause issues in the future.

After assembling the arm, I needed to focus on the hardware controls. This involved properly attaching horns to the motors, as the strings would be wrapped and screwed around them for control. This is an image of the Servo Motors all set up with the Arduino(needed for the power supply), Breadboard(easier for wiring organisation), and the Servo Tester(the main control of the arm)!

Check out the completed Arm through this GIF and other pictures:

I also created a YouTube video of the project with some explanations! Check it out here.

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Still a work in progress and I will document my learnings along with the final project here!