17896258. PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS simplified abstract (Microsoft Technology Licensing, LLC)
Contents
- 1 PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS
- 1.1 Organization Name
- 1.2 Inventor(s)
- 1.3 PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS - A simplified explanation of the abstract
- 1.4 Simplified Explanation
- 1.5 Potential Applications
- 1.6 Problems Solved
- 1.7 Benefits
- 1.8 Potential Commercial Applications
- 1.9 Possible Prior Art
- 1.10 Original Abstract Submitted
PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS
Organization Name
Microsoft Technology Licensing, LLC
Inventor(s)
Parsa Bonderson of Santa Barbara CA (US)
David Alexander Aasen of Santa Barbara CA (US)
Christina Paulsen Knapp of Goleta CA (US)
PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS - A simplified explanation of the abstract
This abstract first appeared for US patent application 17896258 titled 'PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS
Simplified Explanation
The physical layouts of Majorana-based qubits for implementations of pentagonal tilings are described in the patent application. An example quantum device includes a set of tetrons arranged in a lattice to enable pentagonal tilings associated with the set of tetrons. The vertices of the pentagonal tilings relate to the qubits and single qubit operations, while the edges of the pentagonal tilings connect different vertices and relate to 2-qubit operations acting on a pair of qubits connected by a given edge. The 1-qubit Pauli measurements are related to the operations performed on the vertices, and the 2-qubit measurements are related to the operations performed along the edges of the pentagonal tilings.
- Majorana-based qubits for pentagonal tilings:
* Physical layouts described for implementing pentagonal tilings with Majorana-based qubits. * Example quantum device includes a set of tetrons arranged in a lattice for pentagonal tilings. * Vertices of pentagonal tilings relate to qubits and single qubit operations, while edges relate to 2-qubit operations.
Potential Applications
The technology described in the patent application could have potential applications in: - Quantum computing - Quantum information processing - Quantum cryptography
Problems Solved
The technology addresses the following problems: - Efficient arrangement of qubits for complex quantum operations - Enabling pentagonal tilings for specific quantum computing tasks
Benefits
The benefits of this technology include: - Enhanced quantum computing capabilities - Improved efficiency in quantum information processing - Potential for new quantum algorithms and protocols
Potential Commercial Applications
- Quantum Computing Technology for Pentagonal Tilings
Possible Prior Art
There is no known prior art related to Majorana-based qubits for implementing pentagonal tilings.
Unanswered Questions
== How does the arrangement of tetrons in a lattice affect the performance of the quantum device in implementing pentagonal tilings? The specific impact of the lattice arrangement on the efficiency and accuracy of quantum operations is not detailed in the patent application.
== What are the potential challenges in scaling up this technology for practical quantum computing applications? The scalability of the technology and potential challenges in implementing it on a larger scale are not discussed in the patent application.
Original Abstract Submitted
Physical layouts of Majorana-based qubits for implementations of pentagonal tilings are described. An example quantum device comprises a set of tetrons for enabling Majorana-based qubits. The set of tetrons is arranged in a lattice to allow pentagonal tilings associated with the set of tetrons. The vertices of the pentagonal tilings relate to the qubits and single qubit operations, and the edges of the pentagonal tilings (connecting different vertices) relate to 2-qubit operations acting on a pair of qubits connected by a given edge. As an example, the 1-qubit Pauli measurements relate to the operations performed on the vertices associated with the pentagonal tilings and the 2-qubit measurements relate to the operations performed along the edges of the pentagonal tilings.