QUANTUM CIRCUIT FOR TRANSFORMATION OF MIXED STATE VECTORS

Organization Name

International Business Machines Corporation

Inventor(s)

Ismail Yunus Akhalwaya of Emmarentia (ZA)

Shashanka Ubaru of Ossining NY (US)

Kenneth Lee Clarkson of Madison NJ (US)

Mark S. Squillante of Greenwich CT (US)

Vasileios Kalantzis of White Plains NY (US)

Lior Horesh of North Salem NY (US)

QUANTUM CIRCUIT FOR TRANSFORMATION OF MIXED STATE VECTORS - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240020563 titled 'QUANTUM CIRCUIT FOR TRANSFORMATION OF MIXED STATE VECTORS

Simplified Explanation

The patent application describes systems and methods for operating quantum systems. It involves a controller that generates a command signal to control quantum hardware with multiple qubits. The quantum system can sample an input vector represented by the qubits, which includes mixed states with different Hamming weights. The quantum hardware can be controlled to entangle the first set of qubits to a second set of qubits, representing the count of nonzero elements in the input vector. An output vector is generated based on the entanglement, containing states with a specific Hamming weight.

• The patent application describes a system for operating quantum systems.
• A controller generates a command signal to control quantum hardware with multiple qubits.
• The quantum system can sample an input vector represented by the qubits, which includes mixed states with different Hamming weights.
• The quantum hardware can be controlled to entangle the first set of qubits to a second set of qubits, representing the count of nonzero elements in the input vector.
• An output vector is generated based on the entanglement, containing states with a specific Hamming weight.

Potential Applications:

• Quantum computing: This technology can be applied in quantum computing systems to control and manipulate qubits, allowing for more efficient and accurate computations.
• Data analysis: The ability to sample and manipulate input vectors with mixed states can be useful in various data analysis tasks, such as pattern recognition and optimization problems.

Problems Solved:

• Efficient entanglement: The technology solves the problem of efficiently entangling qubits in a quantum system, allowing for more complex computations and information processing.
• Mixed state sampling: The system addresses the challenge of sampling input vectors with mixed states, enabling the analysis of data with diverse characteristics.

Benefits:

• Improved quantum computing performance: The technology enhances the performance of quantum computing systems by enabling efficient entanglement and manipulation of qubits.
• Enhanced data analysis capabilities: The ability to sample and manipulate input vectors with mixed states provides more flexibility and accuracy in data analysis tasks, leading to improved results and insights.

Original Abstract Submitted

systems and methods for operating quantum systems are described. a controller of a quantum system can generate a command signal. the quantum system can include quantum hardware having a plurality of qubits. an interface of the quantum system can control the quantum hardware based on the command signal to sample an input vector represented by the first set of qubits, where the input vector includes mixed states with different hamming weights. the interface can control the quantum hardware to entangle the first set of qubits to the second set of qubits, where the second set of qubits represent a count of nonzero elements in the input vector. the interface can control the quantum hardware to generate an output vector based on the entanglement of the first set of qubits to the second set of qubits, where the output vector includes one or more states having a specific hamming weight.