This course teaches you about quantum computation, basic principles for design of quantum algorithms and experimental realization of quantum computers. You will be taught a very new and direct method on Quantum Mechanics.

You will be introduced to Quantum Algorithms which is a completely new field which hacks into the natures’ computer. Later on you will be taught about another completely new topic ‘Spin Qubits’ to realize quantum computation.

**Assessment**

This course does not involve any written exams. Students need to answer 5 assignment questions to complete the course, the answers will be in the form of written work in pdf or word. Students can write the answers in their own time. Each answer needs to be 200 words (1 Page). Once the answers are submitted, the tutor will check and assess the work.

**Certification**

Edukite courses are free to study. To successfully complete a course you must submit all the assignment of the course as part of the assessment. Upon successful completion of a course, you can choose to make your achievement formal by obtaining your Certificate at a cost of £49.

Having an Official Edukite Certification is a great way to celebrate and share your success. You can:

- Add the certificate to your CV or resume and brighten up your career
- Show it to prove your success

Course Credit: UCB

### Course Curriculum

Module 01 | |||

Quantum Mechanics and Quantum Computation – Overview | 00:08:00 | ||

Quantum Mechanics and Quantum Computation – Double slit experiment part 1 | 00:06:00 | ||

Quantum Mechanics and Quantum Computation – Double slit experiment part 2 | 00:06:00 | ||

Quantum Mechanics and Quantum Computation – Double slit experiment part 3 | 00:13:00 | ||

Quantum Mechanics and Quantum Computation – Double slit experiment part 4 | 00:09:00 | ||

Quantum Mechanics and Quantum Computation – Qubits | 00:10:00 | ||

Module 02 | |||

Quantum Mechanics and Quantum Computation – Geometric representation part 1 | 00:12:00 | ||

Quantum Mechanics – Geometric representation part 2 | 00:08:00 | ||

Quantum Mechanics – Uncertainty principle | 00:11:00 | ||

Quantum Mechanics – k level systems, bra ket notation | 00:16:00 | ||

Quantum Mechanics – Two qubits | 00:06:00 | ||

Quantum Mechanics – Entanglement | 00:09:00 | ||

Quantum Mechanics – EPR Paradox | 00:10:00 | ||

Quantum Mechanics – Bell and EPR | 00:11:00 | ||

Quantum Mechanics – Rotational invariance of Bell state | 00:07:00 | ||

Module 03 | |||

Quantum Mechanics – CHSH Inequality | 00:12:00 | ||

Quantum Mechanics – Bell and local realism | 00:10:00 | ||

Quantum Mechanics – Research Certifiable Randomness | 00:02:00 | ||

Quantum Mechanics – Time evolution of a quantum system | 00:13:00 | ||

Quantum Mechanics – Unitary transforms | 00:11:00 | ||

Quantum Mechanics – Single qubit gates | 00:13:00 | ||

Quantum Mechanics – Two qubit gates and tensor products | 00:23:00 | ||

Quantum Mechanics – No cloning theorem | 00:05:00 | ||

Quantum Mechanics – Bell state circuit | 00:06:00 | ||

Quantum Mechanics – Teleportation part 1 | 00:12:00 | ||

Quantum Mechanics – Teleportation part 2 | 00:11:00 | ||

Quantum Mechanics – Measurement | 00:08:00 | ||

Module 04 | |||

n qubit systems | 00:07:00 | ||

Quantum Mechanics – Manipulating n qubits | 00:08:00 | ||

Quantum Mechanics – Universal family of gatesQuantum Mechanics – | 00:05:00 | ||

Quantum Mechanics – Reversible computation part 1 | 00:14:00 | ||

Quantum Mechanics – Reversible computation part 2 | 00:07:00 | ||

Quantum Mechanics – Fourier sampling part 1 | 00:08:00 | ||

Quantum Mechanics – Fourier sampling part 2 | 00:11:00 | ||

Quantum Mechanics – Simon’s algorithm | 00:17:00 | ||

Quantum Mechanics – 2^n slit experiment | 00:06:00 | ||

Quantum Mechanics – Extended Church Turing thesis | 00:04:00 | ||

Quantum Mechanics – Quantum Fourier transform overview | 00:10:00 | ||

Quantum Mechanics – n th roots of unity | 00:07:00 | ||

Module 05 | |||

Quantum Mechanics – QFTn part 1 | 00:08:00 | ||

QFTn part 2 | 00:10:00 | ||

Quantum Mechanics – QFTn Properties | 00:17:00 | ||

Quantum Mechanics – Quantum factoring Period finding | 00:19:00 | ||

Quantum Mechanics – Quantum factoring Shor’s factoring algorithm | 00:26:00 | ||

Quantum Mechanics – Quantum factoring QFT circuit | 00:22:00 | ||

Quantum Mechanics – Quantum search Needle in a haystack | 00:08:00 | ||

Quantum Mechanics – Quantum search Grover’s algorithm | 00:12:00 | ||

Quantum Mechanics – Quantum search Implementing Grover’s algorithm | 00:21:00 | ||

Module 06 | |||

Quantum Mechanics – Observables part 1 | 00:13:00 | ||

Quantum Mechanics – Observables part 2 | 00:11:00 | ||

Quantum Mechanics – Schrödinger’s equation | 00:19:00 | ||

Quantum Mechanics – Continuous quantum states | 00:09:00 | ||

Quantum Mechanics – Schrödinger’s equation for 1D free particle | 00:12:00 | ||

Quantum Mechanics – Particle in a box | 00:18:00 | ||

Quantum Mechanics – Implementing qubits | 00:05:00 | ||

Quantum Mechanics – Spin as a qubit | 00:07:00 | ||

Quantum Mechanics – Bloch sphere | 00:20:00 | ||

Quantum Mechanics – Stern Gerlach | 00:13:00 | ||

Module 07 | |||

Quantum Mechanics – Pauli spin matrices | 00:13:00 | ||

Quantum Mechanics – Manipu;ating spin Larmor precession | 00:16:00 | ||

Quantum Mechanics – Manipu;ating spin Spin resonance | 00:20:00 | ||

Quantum Mechanics – Manipu;ating spin Classical control | 00:12:00 | ||

Quantum Mechanics – Adiabatic quantum computing intro | 00:04:00 | ||

Quantum Mechanics – Adiabatic quantum computing NP hard optimization problems | 00:08:00 | ||

Quantum Mechanics – Adiabatic quantum optimization | 00:12:00 | ||

Adiabatic quantum computing Local optima, simulated annealing, and tunneling | 00:11:00 | ||

Quantum Mechanics – Adiabatic quantum computing D Wave + project | 00:13:00 | ||

Assessment | |||

Submit Your Assignment | 00:00:00 | ||

Certification | 00:00:00 |

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