Get the best quantum results, every time

Eliminate the guesswork of optimizing quantum applications

Getting the best performance of quantum applications is hard. Errors in quantum computers decrease the accuracy, reliability and performance of your quantum applications.

Commutator improves the performance of your quantum application for you finding the best execution parameters for different quantum computers automatically.

Get execution recommendations
for your Quantum Circuit

After

Before

rz(pi*-0.9153964903) q[0];
rz(pi*-0.9153964903) q[5];
u3(pi*0.5,0,0) q[0];
u3(pi*0.5,pi*1.0,0) q[5];
rx(pi*0.5) q[0];
cx q[0],q[5];
rx(pi*0.4153964903) q[0];
ry(pi*0.5) q[5];
cx q[5],q[0];
rx(pi*-0.5) q[5];
rz(pi*0.5) q[5];
cx q[0],q[5];
u3(pi*0.5,pi*0.9153964903,pi*1.0) q[0];
u3(pi*0.5,pi*0.9153964903,0) q[5];

rz(pi*-0.9153964903) q[1];
rz(pi*-0.9153964903) q[2];

Recommended execution parameters

Hardware	Compilation	Mitigation	Accuracy	Shots	Queue
β	B	Y	0.977	1300	66
δ	A	X	0.975	2800	110
γ	D	X	0.974	1100	195
ε	C	Z	0.974	2100	350
α	C	Z	0.962	2500	25
γ	B	X	0.96	1600	195

How it works

Set up a Quantum Circuit.

Bring your own Quantum Circuit in all the main quantum programming languages. Or use our library of algorithms to get started.

You prioritize execution parameters. We do the work in the background.

Set the priorities that matter to you. Focus on your budget, desired accuracy and time-to-solution.

We return optimal settings for real hardwares. Directly see the improvements that matter to you.

We optimize where and how to run your quantum circuit, to get the best quantum results.

Talk to our experts to learn how Commutator Studios improves your quantum executions.

Commutator Studios supports use cases in:

Chemistry

Pharma

Finance

Logistics

Transportation

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Get the best quantum results, every time

Get execution recommendationsfor your Quantum Circuit

How it works

Get execution recommendations
for your Quantum Circuit