Masaya Norimoto’s research while affiliated with Yokohama National University and other places

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Publications (6)


FIGURE 2. System model with J UTs and K receive antennas.
FIGURE 3. Estimated number of T gates required by each formulation with J = n/ log 2 Lc .
FIGURE 4. A relationship between the number of states smaller than the initial threshold y 0 and a received symbol r in multiuser detection.
FIGURE 7. Impact of power allocation on the optimal number of Grover rotations with SNR = 20dB.
Quantum Speedup for Multiuser Detection With Optimized Parameters in Grover Adaptive Search
  • Article
  • Full-text available

January 2024

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6 Reads

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2 Citations

IEEE Access

Masaya Norimoto

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Taku Mikuriya

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Maximum-likelihood multiuser detection incurs a large computational complexity, and its low-complexity detection scheme suffers from a performance loss, where this tradeoff is inevitable and inherent in classical computation. In this paper, we use the Grover adaptive search (GAS) to break the tradeoff, which is a quantum exhaustive search algorithm guaranteed to obtain the optimal solution, achieving a quadratic speedup. Specifically, we design two specific parameters of GAS to achieve the optimal performance with a reduced complexity: the initial threshold and the number of Grover rotations. The initial threshold of GAS can be optimized using a solution of semi-definite programming, and it is possible to calculate the distribution of the number of solutions smaller than the initial threshold in advance, which depends on instantaneous channel coefficients. In addition, we analyze the number of quantum gates required for GAS and show that the gate count can be reduced by bypassing the higher-order terms in the objective function, leading to a reduced circuit runtime. Our analysis and simulation results demonstrate that the proposed approach achieves the same performance as the optimal maximum-likelihood detection while reducing the query complexity of GAS, implying that the large constant overhead of quadratic speedup can be further reduced.

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Quantum Algorithm for Higher-Order Unconstrained Binary Optimization and MIMO Maximum Likelihood Detection

April 2023

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69 Reads

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25 Citations

IEEE Transactions on Communications

In this paper, we propose a quantum algorithm that supports a real-valued higher-order unconstrained binary optimization (HUBO) problem. This algorithm is based on the Grover adaptive search that originally supported HUBO with integer coefficients. Next, as an application example, we formulate multiple-input multiple-output maximum likelihood detection as a HUBO problem with real-valued coefficients, where we use the Gray-coded bit-to-symbol mapping specified in the 5G standard. The proposed approach allows us to construct an efficient quantum circuit for the detection problem and to analyze specific numbers of required qubits and quantum gates, whereas other conventional studies have assumed that such a circuit is feasible as a quantum oracle. To further accelerate the quantum algorithm, we also derive a probability distribution of the objective function value and determine a unique threshold to sample better states. Assuming a future fault-tolerant quantum computing, our proposed algorithm has the potential for significantly reducing query complexity in the classical domain and providing a quadratic speedup in the quantum domain.


FIGURE 1. Quantum circuit corresponding to E(x) = 1 + x1 − 1.8x2x3x4 and yi = 0.
FIGURE 2. System model of CAP, where the number of APs is NAP = 4 and the number of channels is NCH = 3.
FIGURE 7. Expected query complexity in the quantum domain.
Qubit Reduction and Quantum Speedup for Wireless Channel Assignment Problem

January 2023

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25 Reads

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15 Citations

IEEE Transactions on Quantum Engineering

In this paper, we propose a novel method of formulating an NP-hard wireless channel assignment problem as a higher-order unconstrained binary optimization (HUBO), where the Grover adaptive search (GAS) is used to provide a quadratic speedup for solving the problem. The conventional method relies on a one-hot encoding of the channel indices, resulting in a quadratic formulation. By contrast, we conceive ascending and descending binary encodings of the channel indices, construct a specific quantum circuit, and derive the exact numbers of qubits and gates required by GAS. Our analysis clarifies that the proposed HUBO formulation significantly reduces the number of qubits and the query complexity compared with the conventional quadratic formulation. This advantage is achieved at the cost of an increased number of quantum gates, which we demonstrate can be reduced by our proposed descending binary encoding.


Qubit Reduction and Quantum Speedup for Wireless Channel Assignment Problem

August 2022

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42 Reads

In this paper, we propose a novel method of formulating an NP-hard wireless channel assignment problem as a higher order unconstrained binary optimization (HUBO), where the Grover adaptive search (GAS) is used to provide a quadratic speedup for solving the problem. The conventional method relies on a one-hot encoding of the channel indices, resulting in a quadratic formulation. By contrast, we conceive ascending and descending binary encodings of the channel indices, construct a specific quantum circuit, and derive the exact numbers of qubits and gates required by GAS. Our analysis clarifies that the proposed HUBO formulation significantly reduces the number of qubits and the query complexity compared with the conventional quadratic formulation. This advantage is achieved at the cost of an increased number of quantum gates, which we demonstrate can be reduced by our proposed descending binary encoding.


Fig. 5. System model for MIMO with Nt transmit and Nr receiver antennas.
List of important mathematical symbols
Quantum Speedup for Higher-Order Unconstrained Binary Optimization and MIMO Maximum Likelihood Detection

May 2022

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64 Reads

In this paper, we propose a quantum algorithm that supports a real-valued higher-order unconstrained binary optimization (HUBO) problem. This algorithm is based on the Grover adaptive search that originally supported HUBO with integer coefficients. Next, as an application example, we formulate multiple-input multiple-output maximum likelihood detection as a HUBO problem with real-valued coefficients, where we use the Gray-coded bit-to-symbol mapping specified in the 5G standard. The proposed approach allows us to construct a specific quantum circuit for the detection problem and to analyze specific numbers of required qubits and quantum gates, whereas other conventional studies have assumed that such a circuit is feasible as a quantum oracle. To further accelerate the convergence, we also derive a probability distribution of the objective function value and determine a unique threshold to sample better states for the quantum algorithm. Assuming a future fault-tolerant quantum computer, we demonstrate that the proposed algorithm is capable of reducing the query complexity in the classical domain and providing a quadratic speedup in the quantum domain.

Citations (4)


... Additionally, by optimizing algorithm parameters, query complexity can be further reduced [24,25], although it has been proven that it is impossible to be reduced below o( √ 2 n ) [26] 1 . Since the proposal of the GAS algorithm, its applications have been studied in various fields, including traveling salesman problem (TSP) [25,28], industrial shift scheduling [29], detection problems in wireless communications [17,30], channel allocation problems [3], the construction of binary constant weight codes [31], and the dispersion problem [32]. ...

Reference:

Grover Adaptive Search with Spin Variables
Quantum Speedup for Multiuser Detection With Optimized Parameters in Grover Adaptive Search

IEEE Access

... However, this issue can be avoided by evaluating the objective function values in the classical domain in the step 2), which can correctly evaluate the value of the objective function with real coefficients [17]. Because we will focus on practical use cases where the objective function includes realvalued coefficients, as will be discussed in Sections IV and V, we adopt the algorithm [36] in this paper. ...

Grover Adaptive Search for Joint Maximum-Likelihood Detection of Power-Domain Non-Orthogonal Multiple Access
  • Citing Conference Paper
  • June 2023

... The breakthrough is Gilliam's method proposed in [37] that efficiently constructs a quantum circuit of GAS for arbitrary binary polynomial objective functions. This method has already demonstrated quadratic speedups of some problems, such as maximum likelihood detection [38,39] and wireless channel assignment problem [40,41]. In GAS, its stop policy and the Grover iterations can be appropriately tuned for a fast convergence to the optimal solution [42], demonstrating improvements in the average numbers of classical iterations and total Grover rotations. ...

Qubit Reduction and Quantum Speedup for Wireless Channel Assignment Problem

IEEE Transactions on Quantum Engineering