COMPENSATED MICROWAVE DRIVEN QUBITS

Organization Name

Nederlandse Organisatie voor toegepast-natuurwetenschappelijk Onderzoek TNO

Inventor(s)

Nodar Samkharadze of Delft (NL)

Xiao Xue of Delft (NL)

COMPENSATED MICROWAVE DRIVEN QUBITS - A simplified explanation of the abstract

This abstract first appeared for US patent application 18275173 titled 'COMPENSATED MICROWAVE DRIVEN QUBITS

Simplified Explanation

The abstract describes a method and system for driving a set of qubits using separate microwave gates to apply respective microwave signals to each qubit. By applying electrical signals with shifted phases to the microwave gates, crosstalk between qubits can be at least partially compensated.

• Qubits are provided with separate microwave gates to apply microwave signals.
• A first qubit is driven with a first driving frequency, and a second qubit with a second driving frequency.
• Electrical signals with shifted phases are applied to the microwave gates to compensate for crosstalk.
• The second qubit receives the microwave signal in counterphase to the first qubit.

Potential Applications

This technology could be applied in quantum computing systems to improve the performance and reliability of qubits by reducing crosstalk between them.

Problems Solved

1. Crosstalk between qubits in quantum computing systems. 2. Improving the efficiency and accuracy of qubit operations.

Benefits

1. Enhanced performance of quantum computing systems. 2. Increased reliability and accuracy of qubit operations. 3. Reduction of errors caused by crosstalk.

Potential Commercial Applications

Optimizing quantum computing systems for various industries such as finance, healthcare, and cybersecurity to solve complex problems efficiently and accurately.

Possible Prior Art

There may be prior art related to methods for reducing crosstalk between qubits in quantum computing systems, but specific examples are not provided in this abstract.

Unanswered Questions

How does this technology compare to existing methods for reducing crosstalk in quantum computing systems?

This article does not provide a comparison with existing methods for reducing crosstalk in quantum computing systems. Further research is needed to determine the effectiveness and efficiency of this new approach.

What are the potential limitations or challenges of implementing this technology in practical quantum computing systems?

The abstract does not address any potential limitations or challenges of implementing this technology in practical quantum computing systems. Further investigation is required to understand the practical implications and feasibility of this approach.

Original Abstract Submitted

A method and system are described for driving a set of qubits. A first qubit is provided with a first driving frequency and a second qubit is provided with a second driving frequency. Each qubit is provided with a separate microwave gate configured to apply a respective microwave signal. A first electrical signal including the first driving frequency is applied to the first microwave gate for driving the first qubit. Simultaneously a second electrical signal is applied to the second microwave gate including the first driving frequency shifted in phase with respect to the first electrical signal for generating the second microwave signal with the first driving frequency arriving at the second qubit in counterphase to first microwave signal. This may at least partially compensate crosstalk.