Womanium Quantum+AI 2024 Projects
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Do NOT delete/ edit the format of this read.me file.
Include all necessary information only as per the given format.
- Maximum team size = 3
- While individual participation is also welcome, we highly recommend team participation :)
- All nationalities, genders, and age groups are welcome to participate in the projects.
- All team participants must be enrolled in Womanium Quantum+AI 2024.
- Everyone is eligible to participate in this project and win Womanium grants.
- All successful project submissions earn the Womanium Project Certificate.
- Best participants win Womanium QSL fellowships with Classiq. Please review the eligibility criteria for QSL fellowships in the project description below.
- Click here to view the project description.
All information in this section will be considered for project submission and judging.
Ensure your repository is public and submitted by August 9, 2024, 23:59pm US ET.
Ensure your repository does not contain any personal or team tokens/access information to access backends. Ensure your repository does not contain any third-party intellectual property (logos, company names, copied literature, or code). Any resources used must be open source or appropriately referenced.
Team Member 1:
- Full Name: Hirad Alipanah
- Womanium Program Enrollment ID (see Welcome Email, format- WQ24-xxxxxxxxxxxxxxx): WQ24-6wiZrXsgKidzwRr
Include a comprehensive summary of all important information about your project solution here. All necessary code files and any additional information required to judge your project solution should be included in the repository.
Here, I implemented a case of the Hamiltonian simulation based on the paper of coupled oscilators. The simple case shows the solution for a Hamiltonian with 3 qubits which simulates a system with 2 masses and 3 springs. The circuit is optimized to have depth of no more than 50. With this depth, the results are achieved and is very close to the classical simulations. Also, the description for Hamiltonian simulation of 2 general problems are provided in task 2.
Link a 5min. presentation recording or deck here.