Quantum Instruction Set  Computerphile  Summary and Q&A
TL;DR
Writing software for quantum computers is similar to writing software for traditional computers, but the basic building block is a qubit instead of a bit.
Key Insights
 🖱️ Writing software for quantum computers is similar to writing software for traditional computers but with the use of qubits as the building blocks.
 ❓ Qubits are resourcelike and can represent various physical systems with two states and probabilities.
 🔬 Quantum programming involves manipulating probabilities through instructions like Hadamard and CNOT gates.
 👻 Quantum computers can interact with multiple qubits, allowing for powerful computations.
 ✋ Quantum programming languages and libraries, like PyQuil, provide higherlevel abstractions for writing quantum programs.
 💻 Quantum computers can solve specific problems efficiently, such as the Fourier Transform.
 🏃 Running programs on a quantum computer requires handling noise and collecting statistics to obtain accurate answers.
Transcript
We talked a bit about the hardware, you know, people are working on the hardware of quantum computing, yep What about software? where do you start thinking about that? Writing software for a quantum computer In my opinion is actually not very very different from how we write software for just a normal computer and we think about software in terms o... Read More
Questions & Answers
Q: What is the fundamental difference between writing software for quantum computers and traditional computers?
While the concept of writing instructions is similar, the fundamental building block in quantum computers is a qubit, which can exist in two states with probabilities.
Q: How are qubits represented in quantum computers?
Qubits can be represented by various physical systems, such as photons' polarization or superconducting charge qubits. These systems have two states and probabilities associated with them.
Q: How do qubits interact in a quantum computer?
Qubits in a quantum computer can interact with each other, allowing for powerful computations. Each additional qubit exponentially increases the number of probabilities that can be manipulated.
Q: How are probabilities changed in a quantum computer?
Instructions, such as Hadamard and CNOT gates, are used to change the probabilities of qubits. These instructions act on the probabilities and can be represented by matrices.
Summary & Key Takeaways

Writing software for quantum computers is not very different from writing software for traditional computers.

Qubits are the fundamental building blocks of quantum computers and have two states with probabilities.

Quantum computers can interact with multiple qubits, allowing for powerful computations.

Quantum programming involves changing probabilities through instructions like Hadamard and CNOT gates.