I am looking for BB84 simulation on Qiskit.

Awesome Derek, a fantastic Qiskit Intro! Well done and keep going compiling the tutorials in the same style... really appreciated the condensed and swift walkthrough the code and step by step instructions... 👍

I am a first-year university student in Japan, and I recently became interested in quantum computing after watching videos of IBM's researchers. I hope to specialize in quantum computing and work at IBM in the future. Since my university only offers classes in Japanese, these videos are truly invaluable to me. I plan to study abroad extensively to improve my English skills and fulfill my dream. Thank you very much, Professor John Watrous. I look forward to the next video!

Great talk! Thank you!

I thought statistical independence was the third assumption?

This would be a much richer post if you explained the terms in ⟨S1​⟩∣=∣⟨AB⟩−⟨Ab⟩+⟨aB⟩+⟨ab⟩∣≤2, why three are additive and one subtracted; could any single term be subtracted, if not, why THAT one? Why not some other arrangement? What's the meaning of the terms and the equation? 2.8 is obviously 2* sqrt(2), but you didn't think that was noteworthy?

I wish she'd just use her natural voice ....

Actually, there is no 'realism' assumption in Bell’s theorem. This is a very incorrect presentation of the theorem. The only mathematical assumptions, in addition to 'local causality,' are ‘dichotomic outcomes’ and ‘statistical independence’. This is why it is possible to violate Bell’s inequalities by exploiting detection and memory loopholes.

So did anyone manage to get a job?

keenly looking forward to the next episode (is there going to be one? or, do we go back to the current lengthy ones!)

You´re just selling mainsream QM here!

Hey, 
I love your content and videos, they're really helpful. I am an undergraduate student from Indian Institute of Technology Hyderabad, majoring in Engineering Physics. My major interests are in Quantum Computing, Artificial intelligence and working in a startup as team. I basically want to use these technologies to invent things that make life easier for everyone. I just completed my 2nd year and right now I have a three month long break and I'm kinda of confused about a few things regarding how to proceed and utilize my time in the best way to learn everything. Also about what exactly I need to do to achieve what I want. Is there anyway you guys can help me ?

"We must read the stories of the great saints and yogis so we can go beyond time and space, as they have done." Dungsey Thinley Norbu Rinpoche -- The rest is just words biting their own tails.

We already understood or solved Quantum Mechanics (?) that's why we were Star Trek Starfleet and I co-designed and co-developed practical quantum computers in the 1970s to early 80s now in various companies. Carry on. ;) (now I only know C Programming.) It is always using or leveraging on the "quantum principles you know" and you build "quantum forces" that will automatically do the work for you.

Would love to see Matthew/Jake (or anyone else from the core team) talk about the evolution of Qiskit from early days to 1.0, their thoughts on the language implementation (using more Rust with Python bindings) and the future of the SDK with QEC on the horizon

I would love to see a step-by-step demonstration using Qikskit where the program runs itself. I would love to just be Victor and send Alice and Bob a particle and they would measure the x projection or the y projection and see what they come up with, then have the ability to decide how many tests to run until the value reaches about 2.8. Then just run it again and again and see for myself. Is there a tool that can do this online?

Yeah!

Starting to see how I sound to my parents when explaining classical computing 😭

Thank you Jesse!

i had an opportunity to meet this amazing man and the first thing i said to him was "what's your name?" a shame i will never live down

Quantum computing is our future that will change the world over the night by combining AI.

You should have a look at recent papers about bitnets. Deep Learning using weights of only 1 and 0s. Maybe those architectures could benefit from quantum computing and qubits.

Jessie IS the runtime 😂

An interesting discussion from classical to quantum runtime environment development.

Thank you ladies! Very informative and thank you for being so transparent with such incredible tech.

First 😁

you got PHD in which discipline?

Great presentation.

The video does not explain what a P! is ( for me its a private investigator , Magnum PI) , A search revealed its a Principle Investigator :)

but guy, can we use quantum computing to make starcraft 3???

I was expecting the Qubit's to print "Hello World" 😂 Man it looks like I have a lot to learn.

Good to see IBM leading the way in computer science, well done Qiskit team.

32:51 I realized it's easier to understand the operations by looking at the matrix as a transformer, with the input from the column vector with first column as input 0 and second column as input 1 and output as the row vectors, with first row as output 0 and second row as output 1.

When is someone going to explain why the speed of light varies significantly over time when measured the same way?

Great job explaining. Thank you.

This conversion to QASM does not work anymore in new versions

Very nice and good lecture, thank you! But oh how I wish that you wouldn't speak like that! It is sad that you use "vocal fry" so much. Otherwise you do a good job of explaining the subject

I have to use: pip install pylatexenc

I'm getting the error: "--------------------------------------------------------------------------- ImportError Traceback (most recent call last) Cell In[30], line 1 ----> 1 from qiskit import Aer ImportError: cannot import name 'Aer' from 'qiskit' (C:\Users\veeru\anaconda3\Lib\site-packages\qiskit\__init__.py)"

What is the minimum temperature achieved close to absolute temperature during the operation of a quantum computer can you give a number

Hi @nickbronn , I wish to use VQE for finding the energy at each k-space of a given k-space hamiltonian of lattice system. Can you tell how to include this k parameter into the hamiltonian's pauli operations circuit?

Nice production quality - excellent speaker - great engagement! This video presents an introduction to Bell's theorem. Great work!

I think being able to script these circuits in python is the most elite aspect of this. One thing that I struggle with is abstracting qubit entanglement and measurement operations onto models of systems I’d like to simulate. I don’t think I understand the time space of the operations and the levels/states of qubit modulation I can map to a meaningful value in an experiment. I will watch more though, great episode 😊

Well if gates were assigned to pre hadamard or post hadamard will by far part of highented sensory as direction of eigenvalue and eigenvectors by 4^schrödinder

Thank you for this!

Hi Derek, this is amazing!!! I have one issue that I may need to get your insight into. At the moment I am trying to simulate strongly correlated (you may say maximally entangled) "physics" using the Sachdev-Ye-Kitaev (SYK) model on IBM QP. However, I noticed that in your Ising Model, the Hamiltonian was simulated sequentially (i.e. using trotter steps). In this case, I can not adopt a similar "sequential" approach for the SYK model - since I need to simulate the dynamical evolution of the Hamiltonian. So my question is... is there any way to simulate a dynamically evolving Hamiltonian on IBM QP? Or could there be an approach to mimic maximally entangled systems? Your feedback will be greatly appreciated

Hi, thanks for these lessons! They are incredibly useful. I have a quick question, when we initialized the two qubits q0 and q1 are they automatically in the |0> state? (are they both in the same state..?)

I understood the topics discussed in the video. But when I moved to the Qiskit examples in the reading, I didn't understand anything. Is it because I am lacking in the topics discussed in the video or is it because of my unfamiliarity with the Numpy? Do you think I should rewatch the entire video again?

It's funny that Einstein's best friend at Princeton was Kurt Gödel and yet it never occurred to him that the collapse of the wave function and experiences such as Bell's can be explained due to the non Computability of the decay of the superposition into a single eigenvector.