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Learning quantum finite automata with queries

Published online by Cambridge University Press:  30 November 2023

Daowen Qiu*
Affiliation:
Institute of Quantum Computing and Computer Theory, School of Computer Science and Engineering, Sun Yat-sen University, Guangzhou 510006, China The Guangdong Key Laboratory of Information Security Technology, Sun Yat-sen University, Guangzhou 510006, China
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Abstract

Learning finite automata (termed as model learning) has become an important field in machine learning and has been useful realistic applications. Quantum finite automata (QFA) are simple models of quantum computers with finite memory. Due to their simplicity, QFA have well physical realizability, but one-way QFA still have essential advantages over classical finite automata with regard to state complexity (two-way QFA are more powerful than classical finite automata in computation ability as well). As a different problem in quantum learning theory and quantum machine learning, in this paper, our purpose is to initiate the study of learning QFA with queries (naturally it may be termed as quantum model learning), and the main results are regarding learning two basic one-way QFA (1QFA): (1) we propose a learning algorithm for measure-once 1QFA (MO-1QFA) with query complexity of polynomial time and (2) we propose a learning algorithm for measure-many 1QFA (MM-1QFA) with query complexity of polynomial time, as well.

Type
Paper
Copyright
© The Author(s), 2023. Published by Cambridge University Press

1 Introduction

Learning finite automata has become an important field in machine learning (Kearns and Vazirani, Reference Kearns and Vazirani1994) and has been applied to wide-ranging realistic problems (Higuera, 2005; Vaandrager, Reference Vaandrager2017), for example, smartcards, network protocols, legacy software, robotics and control systems, pattern recognition, computational linguistics, computational biology, data compression, data mining, etc. In Vaandrager (Reference Vaandrager2017), learning finite automata is termed as model learning. In fact, model learning and model checking as well as and model-based testing have intrinsic connections (see the pioneering contribution of Peled et al. (Reference Peled, Vardi and Yannakakis2002) and Higuera (2010)).

Learning finite automata was first considered by Moore (Reference Moore1956) and an exponential-time query algorithm was proposed. In particular, Angluin (Reference Angluin1987) proposed the so-called membership queries (MQ) and equivalence queries (EQ), a ground-breaking method for learning the models of finite automata. For learning deterministic finite automata (DFA), according to Angluin’s algorithm, the learner initially only knows the inputs (i.e. alphabet) of the model to be learned (say $\mathcal{M}$ ), and the aim of the learner is to learn the model by means of two types of queries, that is, MQ and EQ. MQ means that the learner asks what the result (accepting or rejecting) of output is in response to an input sequence, and the oracle answers with accepting or rejecting, while EQ signifies the learner whether a hypothesized machine model (say $\mathcal{H}$ ) is the same as the learned machine, and the oracle answers yes if this is the case. Otherwise “no” is replied and an input string is provided as a counterexample to distinguish $\mathcal{H}$ and $\mathcal{M}$ .

The complexity of queries of Angluin’s algorithm (Angluin, Reference Angluin1987) is polynomial for learning DFA and Mealy machines. Angluin (Reference Angluin1988) proved that DFA cannot be learned in polynomial time by MQ (or EQ) only. Since Angluin’s algorithm was proposed by Angluin (Reference Angluin1987), learning other models of finite automata has been investigated. Tzeng (Reference Tzeng1992) studied learning probabilistic finite automata (PFA) and Markov chains via SD oracle, where SD oracle can answer state distribution, i.e., probability distribution of states for each input string, so it is more powerful than MQ. For learning DFA via SD oracle, a state is replied for each input string, and the query complexity of learning DFA via SD oracle is polynomial (Tzeng, Reference Tzeng1992).

Then Bergadano and Varricchio (Reference Bergadano and Varricchio1996) used MQ and EQ to learn appropriately PFA, and a probably approximately correct learning algorithm (i.e. PAC algorithm) was presented. Learning nondeterministic finite automata (NFA) was studied by Bollig (2009). In recent years, Angluin et al. (Reference Angluin, Eisenstat and Fisman2015) initiated the research of learning alternating automata, and Berndt et al. (Reference Berndt, Liśkiewicz, Lutter and Reischuk2017) further solved the learning problem of residual alternating automata.

A natural inquiry is that SD oracle seems too strong. However, it was showed by Tzeng (Reference Tzeng1992) that SD oracle is actually not too strong for learning DFA and PFA if the query complexity is required to be polynomial, because learning a consistency problem related to DFA and PFA via SD oracle is still NP-complete (Tzeng, Reference Tzeng1992). In this paper, we use an AD oracle for learning quantum finite automata (QFA) in polynomial time, that is, AD oracle can answer a state of superposition for each input string, i.e., amplitude distribution of states. Similarly it follows that using AD oracle to learn a consistency problem related to reversible finite automata (RFA) and MO-1QFA is NP-complete.

Quantum machine learning (QML) was early considered by Bshouty and Jackson (Reference Bshouty and Jackson1999) with learning from quantum examples, and then quantum learning theory (Arunachalam and de Wolf, Reference Arunachalam and de Wolf2017) as an important theoretical subject of QML has been deeply developed. Quantum learning theory (Arunachalam and de Wolf, Reference Arunachalam and de Wolf2017) includes models of quantum exact learning, quantum PAC learning, and quantum agnostic learning; these models are combinations of corresponding classical learning models with quantum computing (in a way, quantum query algorithms). We further review quantum learning theory and QML more specifically.

We first recall quantum learning theory, which studies the theoretical aspects of QML. As pointed out above, Bshouty and Jackson (Reference Bshouty and Jackson1999) showed that all PAC-learnable function classes are learnable in the quantum models, and notably, Servedio and Gortler (Reference Servedio and Gortler2004) studied quantum versions of Angluin’s model of exact learning from MQ and Valiant’s PAC model of learning from random examples. Then, Aaronson (Reference Aaronson2007) investigated learning quantum states, and Zhang (Reference Zhang2010) further investigated the quantum PAC learning model. Gavinsky (2012) initialed a new quantum learning model called predictive quantum, which is the quantum analogue of PAC, and afterwards, Belovs (Reference Belovs2015) investigated the junta learning problem by designing quantum algorithms. Quantum deep learning was studied by Wiebe (2016), and Cheng et al. (Reference Cheng, Hsieh and Yeh2016) provided a framework to analyze learning matrices in the Schatten class. A detailed survey concerning quantum learning theory was presented by Arunachalam and de Wolf (Reference Arunachalam and de Wolf2017), and Arunachalam and de Wolf (Reference Arunachalam and de Wolf2018) further showed that classical and quantum sample complexities are equal up to constant factors for every concept class.

Now we simply recall the development of quantum machine learning (QML). Harrow et al. (Reference Harrow, Hassidim and Lloyd2009) proposed a quantum algorithm for solving systems of linear equations, which may be thought of the start of studying quantum machine learning. Then, Wiebe (2012) proposed a quantum linear regression algorithm by virtue of HHL algorithm. Lloyd et al. (Reference Lloyd, Mohseni and Rebentrost2014) proposed a quantum version of principal component analysis dimension reduction algorithm. Also, quantum matrix inversion was employed in a supervised discriminative learning algorithm (Rebentrost et al., Reference Rebentrost, Mohseni and Lloyd2014). Schuld et al. (Reference Schuld, Sinayskiy and Petruccione2015) presented a comprehensive perspective on quantum machine learning, and Cong and Duan (Reference Cong and Duan2016) proposed a quantum data dimension reduction algorithm. Biamonte et al. (Reference Biamonte, Wittek, Pancotti, Rebentrost, Wiebe and Lloyd2017) focused on utilizing a quantum computer to analyze classical or quantum data encoded as quantum states, and Kerenidis and Prakash (Reference Kerenidis and Prakash2017) proposed a quantum algorithm for recommendation systems. Lloyd and Weedbrook (Reference Lloyd and Weedbrook2018) changed a classical generative adversarial network to obtain a quantum generative adversarial network, and Mitarai et al. (Reference Mitarai, Negoro, Kitagawa and Fujii2018) constructed a quantum neural network model. Zhao et al. (Reference Zhao, Pozas-Kerstjens, Rebentrost and Wittek2019) designed quantum Bayesian neural networks, and Benedetti (2019) provided an overview of these models’ components and investigated their application. Recently, an application of machine learning techniques to quantum devices was found by Marquardt (Reference Marquardt2021). Huang et al. (Reference Huang, Broughton and Cotler2022) confirmed that QML can more effectively learn the operating rules of the physical world than any classical machine learning method, and then, prediction of the evolution of quantum systems has been achieved successfully in Rodriguez et al. (Reference Rodriguez, Ullah, Espinosa, Dral and Kananenka2022). More recently, Meyer et al. (Reference Meyer, Mularski, Gil-Fuster, Mele, Arzani, Wilms and Eisert2023) explored how symmetries in learning problems can be exploited to create quantum learning models, and Krenn et al. (Reference Krenn, Landgraf, Foesel and Marquardt2023) discussed the application of machine learning and artificial intelligence in analyzing quantum measurements.

However, learning QFA is still a pending problem to be studied, and this is the main goal of this paper. QFA can be thought of as a theoretical model of quantum computers in which the memory is finite and described by a finite-dimensional state space (Ambainis and Yakaryilmaz, Reference Ambainis, Yakaryilmaz and Pin2021; Bhatia and Kumar, Reference Bhatia and Kumar2019; Gruska, Reference Gruska1999; Qiu et al., Reference Qiu, Li, Mateus, Gruska and Wang2012). An excellent and comprehensive survey on QFA was presented by Ambainis and Yakaryilmaz (Reference Ambainis, Yakaryilmaz and Pin2021). Moreover, QFA have been studied significantly in physical experiment (Mereghetti et al., Reference Mereghetti, Palano and Cialdi2020; Plachta et al., Reference Plachta, Hiekkamäki, Yakaryilmaz and Fickler2022; Tian, 2019).

One-way QFA (1QFA) were firstly proposed and studied by Moore and Crutchfield (Reference Moore and Crutchfield2000), Kondacs and Watrous (Reference Kondacs and Watrous1997), and then Ambainis and Freivalds (Reference Ambainis and Freivalds1998), Brodsky and Pippenger (Reference Brodsky and Pippenger2002), and other authors (e.g., the references in Ambainis and Yakaryilmaz (Reference Ambainis, Yakaryilmaz and Pin2021), Qiu et al. (Reference Qiu, Li, Mateus, Gruska and Wang2012), and Bhatia and Kumar (Reference Bhatia and Kumar2019)), where “1” means “one-way,” that is, the tape-head moves only from the left side to the right side. The decision problems regarding the equivalence of 1QFA and the minimization of states of 1QFA have been studied in Qiu et al. (Reference Qiu, Li, Mateus, Gruska and Wang2012),Mateus (2012), Qiu et al. (Reference Qiu, Li, Zou, Mateus and Gruska2011), and Li and Qiu (Reference Li and Qiu2006, Reference Li and Qiu2008).

More specifically, measure-once one-way QFA (MO-1QFA) were initiated by Moore and Crutchfield (Reference Moore and Crutchfield2000) and measure-many one-way QFA (MM-1QFA) were studied first by Kondacs and Watrous (Reference Kondacs and Watrous1997). In MO-1QFA, there is only a measurement for computing each input string, performing after reading the last symbol; in contrast, in MM-1QFA, measurement is performed after reading each symbol, instead of only the last symbol. Then other 1QFA were also proposed and studied by Ambainis et al., Nayak, Hirvensalo, Yakaryilmaz and Say, Paschen, Ciamarra, Bertoni et al., Qiu and Mateus et al. as well other authors (e.g., the references in Ambainis and Yakaryilmaz (Reference Ambainis, Yakaryilmaz and Pin2021)), including: Latvian QFA (Ambainis et al., Reference Ambainis, Beaudry, Golovkins, Kikusts, Mercer and Therien2006), QFA with control language (Bertoni et al., Reference Bertoni, Mereghetti and Palano2003), 1QFA with ancilla qubits (1QFA-A) (Paschen, Reference Paschen2000), one-way quantum finite automata together with classical states (1QFAC) (Qiu et al., Reference Qiu, Li, Mateus and Sernadas2015), and other 1QFA such as Nayak-1QFA (Na-1QFA), General-1QFA (G-1QFA), and fully 1QFA (Ci-1QFA), where G-1QFA, 1QFA-A, Ci-1QFA, 1QFA-CL, and 1QFAC can recognize all regular languages with bounded error. For more details, we can refer to Ambainis and Yakaryilmaz (Reference Ambainis, Yakaryilmaz and Pin2021), Qiu et al. (Reference Qiu, Li, Mateus, Gruska and Wang2012), and Bhatia and Kumar (Reference Bhatia and Kumar2019).

MO-1QFA have advantages over crisp finite automata in state complexity for recognizing some languages (Bhatia and Kumar, Reference Bhatia and Kumar2019; Qiu et al., Reference Qiu, Li, Mateus, Gruska and Wang2012). Mereghetti et al. (Reference Mereghetti, Palano and Cialdi2020) realized an MO-1QFA with optic implementation and the state complexity of this MO-1QFA has exponential advantages over DFA and NFA as well as PFA (Paz, Reference Paz1971). MM-1QFA have stronger computing power than MO-1QFA (Brodsky and Pippenger, Reference Brodsky and Pippenger2002), but both MO-1QFA and MM-1QFA accept with bounded error only proper subsets of regular languages. Indeed, Brodsky and Pippenger (Reference Brodsky and Pippenger2002) proved that the languages accepted by MO-1QFA with bounded error are exactly reversible languages that are accepted by RFA. RFA have three different definitions and were named as group automata, BM-reversible automata, and AF-reversible automata (see Qiu (Reference Qiu2007)), respectively. In particular, these three definitions were proved to be equivalent in Qiu (Reference Qiu2007).

The remainder of this paper is organized as follows. In Section 2, in the interest of readability, we first introduce basics in quantum computing, then one-way QFA are recalled and we focus on reviewing MO-1QFA and MM-1QFA. The main contributions are in Sections 3 and 4. In Section 3, we first show the appropriate oracle to be used, that is, ${\boldsymbol{AA}}$ is not strong enough for learning RFA and MO-1QFA with polynomial time, and a more powerful oracle (named as ${\boldsymbol{AD}}$ oracle) is thus employed. With ${\boldsymbol{AD}}$ oracle, we design an algorithm for learning MO-1QFA with polynomial time, and the correctness and complexity of algorithm are proved and analyzed in detail. Afterwards, in Section 4 we continue to design an algorithm for learning MM-1QFA with polynomial time. Finally, the main results are summarized in Section 5, and further problems are mentioned for studying.

2 Preliminaries on Quantum Computing and QFA

For the sake of readability, in this section we outline basic notations and principles in quantum computing and review the definitions of MO-1QFA, MM-1QFA, and RFA. For more details, we can refer to Nielsen and Chuang (Reference Nielsen and Chuang2000) and Qiu et al. (Reference Qiu, Li, Mateus, Gruska and Wang2012), Say and Yakaryılmaz (2014), Ambainis and Yakaryilmaz (Reference Ambainis, Yakaryilmaz and Pin2021), and Bhatia and Kumar (Reference Bhatia and Kumar2019).

2.1 Basics in quantum computing

Let $\mathbb{C}$ denote the set of all complex numbers, $\mathbb{R}$ the set of all real numbers, and $\mathbb{C}^{n\times m}$ the set of $n\times m$ matrices having entries in $\mathbb{C}$ . Given two matrices $A\in \mathbb{C}^{n\times m}$ and $B\in\mathbb{C}^{p\times q}$ , their tensor product is the $np\times mq$ matrix, defined as

$$A\otimes B=\begin{bmatrix} A_{11}B & \dots & A_{1m}B \\ \vdots & \ddots & \vdots \\ A_{n1}B &\dots & A_{nm}B \ \end{bmatrix}.$$

$(A\otimes B)(C\otimes D)=AC\otimes BD$ holds if the multiplication of matrices is satisfied.

If $MM^\dagger=M^\dagger M=I$ , then matrix $M\in\mathbb{C}^{n\times n}$ is unitary, where $\dagger$ denotes conjugate-transpose operation. M is said to be Hermitian if $M=M^\dagger$ . For n-dimensional row vector $x=(x_1,\dots, x_n)$ , its norm $||x||$ is defined as $||x||=\big(\sum_{i=1}^n x_ix_i^{*}\big)^{\frac{1}{2}}$ , where symbol $*$ denotes conjugate operation. Unitary operations preserve the norm, i.e., $||xM||=||x||$ for each $x\in \mathbb{C}^{1\times n}$ and any unitary matrix $M\in\mathbb{C}^{n\times n}$ .

According to the basic principles of quantum mechanics (Nielsen and Chuang, Reference Nielsen and Chuang2000), a state of quantum system can be described by a unit vector in a Hilbert space. More specifically, let $B=\{q_1,\dots,q_n\}$ associated with a quantum system denote a basic state set, where every basic state $q_i$ can be represented by an n-dimensional row vector $\langle q_i|=(0\dots1\dots0)$ having only 1 at the ith entry (where $\langle \cdot|$ is Dirac notation, i.e., bra-ket notation). At any time, the state of this system is a superposition of these basic states and can be represented by a row vector $\langle \phi|=\sum_{i=1}^nc_i\langle q_i|$ with $c_i\in\mathbb{C}$ and $\sum_{i=1}^n|c_i|^2=1$ ; $|\phi\rangle$ represents the conjugate-transpose of $\langle \phi|$ . So, the quantum system is described by Hilbert space $\mathcal{H}_Q$ spanned by the base $\{|q_i\rangle: i=1,2,\dots,n\}$ , i.e. $\mathcal{H}_Q=span\{| q_i\rangle: i=1,2,\dots,n\}$ .

The state evolution of quantum system complies with unitarity. Suppose the current state of system is $|\phi\rangle$ . If it is acted on by some unitary matrix (or unitary operator) $M_1$ , then $|\phi\rangle$ is changed to the new current state $M_1|\phi\rangle$ ; if the second unitary matrix, say $M_2$ , is acted on $M_1|\phi\rangle$ , then $M_1|\phi\rangle$ is changed to $M_2 M_1|\phi\rangle$ . So, after a series of unitary matrices $M_1, M_2, \ldots, M_k$ are performed in sequence, the system’s state becomes $M_kM_{k-1}\cdots M_1|\phi\rangle$ .

To get some information from the quantum system, we need to make a measurement on its current state. Here we consider projective measurement (i.e. von Neumann measurement). A projective measurement is described by an observable that is a Hermitian matrix $\mathcal{O}=c_1P_1+\dots +c_s P_s$ , where $c_i$ is its eigenvalue and, $P_i$ is the projector onto the eigenspace corresponding to $c_i$ . In this case, the projective measurement of $\mathcal{O}$ has result set $\{c_i\}$ and projector set $\{P_i\}$ . For example, given state $|\psi\rangle$ is made by the measurement $\mathcal{O}$ , then the probability of obtaining result $c_i$ is $\|P_i|\psi\rangle\|^2$ and the state $|\psi\rangle$ collapses to $\frac{P_i|\psi\rangle}{\|P_i|\psi\rangle\|}$ .

2.2 Review of one-way QFA and RFA

For non-empty set $\Sigma$ , by $\Sigma^{*}$ we mean the set of all finite length strings over $\Sigma$ , and $\Sigma^n$ denotes the set of all strings over $\Sigma$ with length n. For $u\in \Sigma^{*}$ , $|u|$ is the length of u; for example, if $u=x_{1}x_{2}\ldots x_{m}\in \Sigma^{*}$ where $x_{i}\in \Sigma$ , then $|u|=m$ . For set S, $|S|$ denotes the cardinality of S.

2.2.1 MO-1QFA

We recall the definition of MO-1QFA. An MO-1QFA with n states and input alphabet $\Sigma$ is a five-tuple

(1) \begin{equation}\mathcal{M}=(Q, |\psi_0\rangle,\{U(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r) \end{equation}

where

  • $Q=\{|q_1\rangle,\dots,|q_n\rangle\}$ consist of an orthonormal base that spans a Hilbert space $\mathcal{H}_Q$ ( $|q_i\rangle$ is identified with a column vector with the ith entry 1 and the others 0); at any time, the state of $\mathcal{M}$ is a superposition of these basic states;

  • $|\psi_0\rangle\in \mathcal{H}$ is the initial state;

  • for any $\sigma\in \Sigma$ , $U(\sigma)\in \mathbb{C}^{n\times n}$ is a unitary matrix;

  • $Q_a, Q_r\subseteq Q$ with $Q_a\cup Q_r=Q$ and $Q_a\cap Q_r=\emptyset$ are the accepting and rejecting states, respectively, and it describes an observable by using the projectors $P(a)=\sum_{|q_i\rangle\in Q_a}|q_i\rangle\langle q_i|$ and $P(r)=\sum_{|q_i\rangle\in Q_r}|q_i\rangle\langle q_i|$ , with the result set $\{a,r \}$ of which “a” and “r” denote “accepting” and “rejecting”, respectively. Here Q consists of accepting and rejecting sets.

Given an MO-1QFA $\mathcal{M}$ and an input word $s=x_1\dots x_{n}\in\Sigma^{*}$ , then starting from $|\psi_0\rangle$ , $U(x_1),\dots,U(x_n)$ are applied in succession, and at the end of the word, a measurement $\{P(a),P(r)\}$ is performed with the result that $\mathcal{M}$ collapses into accepting states or rejecting states with corresponding probability. Hence, the probability $L_\mathcal{M}(x_1\dots x_n)$ of $\mathcal{M}$ accepting w is defined as:

(2) \begin{align}L_\mathcal{M}(x_1\dots x_n)=\|P(a)U_s|\psi_0\rangle\|^2\end{align}

where we denote $U_s=U_{x_n}U_{x_{n-1}}\cdots U_{x_1}$ .

2.2.2 RFA

Now we recollect RFA. As mentioned above, there are three equivalent definitions for RFA (Qiu, Reference Qiu2007), that is, group automata, BM-reversible automata, and AF-reversible automata. Here we describe group automata. First we review DFA. A DFA $G=(S, s_0, \Sigma, \delta, S_a)$ , where S is a finite state set, $s_0\in S$ is its initial state, $S_a\subseteq S$ is its accepting state set, $\Sigma$ is an input alphabet, and $\delta$ is a transformation function, i.e., a mapping $\delta: S\times \Sigma\rightarrow S$ .

An RFA (group automaton) $G=(S, s_0, \Sigma, \delta, S_a)$ is DFA and satisfies that for any $q\in S$ and any $\sigma\in\Sigma$ , there is unique $p\in S$ such that $\delta(p,\sigma)=q$ .

The languages accepted by MO-1QFA with bounded error are exactly the languages accepted by RFA (Brodsky and Pippenger, Reference Brodsky and Pippenger2002). In fact, RFA are the special cases of MO-1QFA, and this is showed by the following proposition.

Proposition 1. (1) For any MO-1QFA $\mathcal{M}=(Q, |\psi_0\rangle,\{U(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r) $ with $|\psi_0\rangle\in Q$ , if all entries in $U(\sigma)$ for each $\sigma\in \Sigma$ are either 0 or 1, then $\mathcal{M}$ is actually a group automaton. (2) If $G=(S, s_0, \Sigma, \delta, S_a)$ is a group automaton, then G is actually an MO-1QFA.

Proof.

  1. (1) Suppose the base states $Q=\{|q_i\rangle: i=1,2,\ldots,n\}$ , where $|q_i\rangle$ is an n-dimensional column vector with the ith entry 1 and the others 0. Let $|\psi_0\rangle=|q_{i_0}\rangle$ for some $i_0\in \{1,2,\ldots,n\}$ . It is clear that $U(\sigma)$ (for each $\sigma\in\Sigma$ ) is a permutation matrix and therefore $U(\sigma)$ is also a bijective mapping from Q to Q. So, $\mathcal{M}$ is a group automaton.

  2. (2) If $G=(S, s_0, \Sigma, \delta, S_a)$ is a group automaton with $|S|=n$ , then we denote $S=\{q_1,q_2,\ldots, q_n\}$ and $s_0$ is some $q_i\in S$ . According to the definition of group automata, for each $\sigma\in\Sigma$ , $\delta(\cdot,\sigma)$ is a bijective mapping from S to S. So, we can identify $q_i$ with an n-dimensional column vector with the ith entry 1 and the others 0. Then for each $\sigma\in\Sigma$ , $\delta(\cdot,\sigma)$ induces a unitary matrix $U(\sigma)$ acting on the n-dimensional Hilbert space spanned by the base states S. Finally, $S_a\subseteq S$ and $S_r=S\setminus S_a$ are accepting and rejecting sets of states, respectively. As a result, G is actually equivalent to an MO-1QFA.

2.2.3 MM-1QFA

We review the definition of MM-1QFA. Formally, given an input alphabet $\Sigma$ and an end-maker $\$\notin\Sigma$ , an MM-QFA with n states over the working alphabet $\Gamma=\Sigma\cup\{\$\}$ is a six-tuple $\mathcal{M}=(Q, |\psi_0\rangle,\{U(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r,Q_g)$ , where

  • Q, $|\psi_0\rangle$ , and $U(\sigma)$ ( $\sigma\in \Gamma$ ) are defined as in the case of MO-1QFA; $Q_a,Q_r,Q_g$ are disjoint to each other and represent the accepting, rejecting, and going states, respectively.

  • The measurement is described by the projectors P(a), P(r), and P(g), with the results in $\{a,r,g \}$ of which “a,” “r,” and “g” denote “accepting,” “rejecting,” and “going on,” respectively.

Any input word w to MM-1QFA is in the form: $w\in\Sigma^{*}\$$ , with symbol $\$$ denoting the end of a word. Given an input word $x_1\dots x_n\$$ where $x_1\dots x_n\in \Sigma^n$ , MM-1QFA $\mathcal{M}$ performs the following computation:

  • 1. Starting from $|\psi_0\rangle$ , $U(x_1)$ is applied, and then we get a new state $|\phi_1\rangle= U(x_1)|\psi_0\rangle$ . In succession, a measurement of $\mathcal{O}$ is performed on $|\phi_1\rangle$ , and then the measurement result i ( $i\in \{a,g,r\}$ ) is yielded as well as a new state $|\phi_1^{i}\rangle=\frac{P(i)|\phi_1\rangle}{\sqrt{p_1^i}}$ is obtained, with corresponding probability $p_1^i=||P(i)|\phi_1\rangle||^2$ .

  • 2. In the above step, if $|\phi_1^{g}\rangle$ is obtained, then starting from $|\phi_1^{g}\rangle$ , $U(x_2)$ is applied and a measurement $\{P(a),P(r),P(g)\}$ is performed. The evolution rule is the same as the above step.

  • 3. The process continues as far as the measurement result “g” is yielded. As soon as the measurement result is “a” (“r”), the computation halts and the input word is accepted (rejected).

Thus, the probability $L_\mathcal{M}(x_1\dots x_n)$ of $\mathcal{M}$ accepting w is defined as:

(3) \begin{align} &L_\mathcal{M}(x_1\dots x_{n})\end{align}

(4) \begin{align}=&\sum^{n+1}_{k=1}||P(a)U(x_k) \prod^{k-1}_{i=1}\big(P(g)U(x_i)\big) |\psi_0\rangle ||^2,\end{align}

or equivalently,

(5) \begin{align}&L_\mathcal{M}(x_1\dots x_{n})\end{align}

(6) \begin{align}=&\sum^{n}_{k=0}||P(a)U(x_{k+1}) \prod^{k}_{i=1}\big(P(g)U(x_i)\big) |\psi_0\rangle ||^2,\end{align}

where, for simplicity, we can denote $\$$ by $x_{n+1}$ if no confusion results.

3 Learning MO-1QFA

First we recall a definition concerning model learning with an oracle in polynomial time.

Definition 1. (Tzeng, Reference Tzeng1992) Let R be a class to be learned and $O_{{\bf R}}$ be an oracle for R. Then R is said to be polynomially learnable using the oracle $O_{{\bf R}}$ if there is a learning algorithm L and a two-variable polynomial p such that for every target $r \in \textbf{R}$ of size n to be learned, L runs in time p(n, m) at any point and outputs a hypothesis that is equivalent to r, where m is the maximum length of data returned by $O_{{\bf R}}$ so far in the run.

In order to learn a model with polynomial time via an oracle, we hope this oracle is as weaker as possible. For learning MO-1QFA, suppose an oracle can only answer the amplitudes of accepting states for each input string, then can we learn MO-1QFA successfully with polynomial time via such an oracle? We name such an oracle as ${\boldsymbol{AA}}$ oracle. For clarifying this point, we try to use ${\boldsymbol{AA}}$ oracle to learning DFA. In this case, ${\boldsymbol{AA}}$ oracle can answer if it is either an accepting state or a rejecting state for each input string. Equivalently, ${\boldsymbol{AA}}$ oracle is exactly MQ for learning DFA as the target model. Therefore, learning DFA via ${\boldsymbol{AA}}$ oracle is not polynomial by virtue of the following Angluin’s result (Angluin, Reference Angluin1988).

Theorem 1. (Angluin, Reference Angluin1988) DFA are not polynomially learnable using the MQ oracle only.

In fact, in 2007 a stronger result was proved in Tîrnăucă and Knuutila (2007) that 0-reversible automata (i.e., a 0-reversible automaton is defined as a RFA with only one accepting state (Angluin, Reference Angluin1982)) are not learnable by using MQ only. That can be described by the following theorem.

Theorem 2. (Tîrnăucă and Knuutila, 2007) Any RFA with only one accepting state is not learnable by using MQ only.

Therefore, we have the following proposition.

Proposition 2. DFA and RFA as well as MO-1QFA are not learnable using ${\boldsymbol{AA}}$ oracle only.

Proof. Due to the above Theorem 2, we know that any RFA is not learnable by using MQ only. Since RFA are special cases of DFA and MO-1QFA, we obtain that neither DFA nor MO-1QFA is learnable by using MQ only.

For learning DFA and RFA, ${\boldsymbol{AA}}$ oracle is exactly equal to MQ oracle, so we conclude that DFA and MO-1QFA are not learnable using ${\boldsymbol{AA}}$ oracle only.

So, we consider a stronger oracle, named as ${\boldsymbol{AD}}$ oracle that can answer all amplitudes (instead of the amplitudes of accepting states only) of the superposition state for each input string. For example, for quantum state $|\psi\rangle=\sum_{i=1}^{n}\alpha_i|q_i\rangle$ where $\sum_{i=1}^{n}|\alpha_i|^2=1$ , ${\boldsymbol{AA}}$ oracle can only answer the amplitudes of accepting states in $\{|q_1\rangle, |q_2\rangle, \ldots, |q_n\rangle\}$ , but ${\boldsymbol{AD}}$ oracle can answer the amplitudes for all states in $\{|q_1\rangle, |q_2\rangle, \ldots, |q_n\rangle\}$ . Using ${\boldsymbol{AD}}$ oracle, we can prove that MO-1QFA and MM-1QFA are polynomially learnable. Therefore, for learning DFA or RFA, ${\boldsymbol{AD}}$ oracle can answer a concrete state for each input string, where the concrete state is the output state of the target automaton to be learned.

First we can easily prove that RFA are linearly learnable via ${\boldsymbol{AD}}$ oracle, and this is the following proposition.

Proposition 3. Let RFA $G=(S, s_0, \Sigma, \delta, S_a)$ be the target to be learned. Then G is linearly learnable via using ${\boldsymbol{AD}}$ oracle with query complexity at most $|S||\Sigma|$ .

Proof. First, ${\boldsymbol{AD}}$ oracle can answer the initial state $s_0$ via inputting empty string. Then by taking $s_0$ as a vertex, we use pruning algorithm of decision tree to obtain all states in G while accepting states are marked as well. It is easy to know that the query complexity is $O(|S||\Sigma|)$ .

Our main concern is whether ${\boldsymbol{AD}}$ oracle is too strong, that is to say, whether ${\boldsymbol{AD}}$ oracle possesses too much information for our learning tasks. To clarify this point partially, we employ a consistency problem that, in a way, demonstrates ${\boldsymbol{AD}}$ oracle is really not too strong for our model learning if the time complexity is polynomial. So, we first recall an outcome from Tzeng (Reference Tzeng1992).

Theorem 3. (Tzeng, Reference Tzeng1992) For any alphabet $\Sigma$ and finite set $S=\{q_1,q_2,\ldots,q_n\}$ , the following problem is NP-complete: Given a set D with $D\subseteq \Sigma^*\times S$ , determine whether there is a DFA $G=(S_1, s_0, \Sigma, \delta, S_a)$ such that for any $(x,q)\in D$ , $\delta(s_0,x)=q$ , where $p\in S_1$ if and only if $ (x,p)\in D $ for some $x\in \Sigma^*$ .

Remark 1. In above theorem, each element in D consists of a string in $\Sigma^*$ and a state in S, so D can be identified with the information carried by ${\boldsymbol{AD}}$ oracle in order to learn a DFA. That is to say, even if an ${\boldsymbol{AD}}$ oracle holds so much information like D contained in a DFA in this way, it is still not easy (NP-complete) to learn a consistent DFA. To a certain extent, ${\boldsymbol{AD}}$ oracle is not too strong to learn a DFA. Since constructing RFA is not easier than constructing DFA and RFA are special MO-1QFA, we use ${\boldsymbol{AD}}$ oracle for learning MO-1QFA and MM-1QFA. However, we still do not know what is the weakest oracle to learn MO-1QFA and MM-1QFA with polynomial-time query complexity.

Let $\mathcal{M}=(Q, |\psi_0\rangle,\{U(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r) $ be the target MO-1QFA to be learned, where, as the case of learning PFA (Tzeng, Reference Tzeng1992), the learner is supposed to have the information of $Q, Q_a, Q_r$ , but the other parameters are to be learned by mean of querying the oracle for achieving an equivalent MO-1QFA (more concretely, for each $\sigma\in\Sigma$ , unitary matrix $V(\sigma)$ corresponding to $U(\sigma)$ needs to be determined, but it is possible that $V(\sigma)\not=U(\sigma)$ ). For any $x\in\Sigma^*$ , ${\boldsymbol{AD}}(x)$ can answer an amplitude distribution that is exactly equivalent to a state of superposition corresponding to the input string x, more exactly, ${\boldsymbol{AD}}(x)$ can answer the same state as $U(\sigma_k)U(\sigma_{k-1})\cdots U(\sigma_1)|\psi_0\rangle$ where $x=\sigma_1\sigma_2\cdots\sigma_k$ . From now on, we denote $U(x)=U(\sigma_k)U(\sigma_{k-1})\cdots U(\sigma_1)$ for $x=\sigma_1\sigma_2\cdots\sigma_k$ .

We outline the basic idea and method for designing the learning algorithm of MO-1QFA $\mathcal{M}$ . First, the initial state can be learned from ${\boldsymbol{AD}}$ oracle by querying empty string $\varepsilon$ . Then by using ${\boldsymbol{AD}}$ oracle we continue to search for a base of the Hilbert space spanned by $\{v^*=U(x)|\psi_0\rangle: x\in\Sigma^*\}$ . This procedure will be terminated since the dimension of the space is at most $|Q|$ . In fact, we can prove this can be finished in polynomial time. Finally, by virtue of the learned base and solving groups of linear equations we can conclude $V(\sigma)$ for each $\sigma\in\Sigma$ . We prove these results in detail following the algorithm and now present Algorithm 1 for learning MO-1QFA as follows.

Algorithm 1 Algorithm for learning MO-1QFA $\mathcal{M}=(Q, |\psi_0\rangle,\{U(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r) $

Next we prove the correctness of Algorithm 1 and then analyze its complexity. First we prove that Step 1 to Step 12 in Algorithm 1 can produce a set of vectors $\mathcal{B}$ consisting of a base of space spanned by $\{v^*(x)| x\in\Sigma^*\}$ , where $v^*(x)=\boldsymbol{AD}(x)$ is actually the vector replied by oracle $\boldsymbol{AD}$ for input string x, that is, $v^*(x)={\boldsymbol{AD}}(x)=U(\sigma_k)U(\sigma_{k-1})\ldots U(\sigma_1)|\psi_0\rangle$ , for $x=\sigma_1\sigma_2\ldots\sigma_k$ .

Proposition 4. In Algorithm 1 for learning MO-1QFA, the final set of vectors $\mathcal{B}$ consists of a base of Hilbert space $span\{v^*(x)| x\in\Sigma^*\}$ that is spanned by $\{v^*(x)| x\in\Sigma^*\}$ .

Proof. From the algorithm procedure we can assume that $\mathcal{B}=\{v^*(x_1), v^*(x_2),\ldots,v^*(x_m)\}$ for some m, where it is clear that some $x_i$ equals to $\varepsilon$ , and for any $x\in\Sigma^*$ , there are $x_j$ and $y\in\Sigma^*$ such that $x=x_jy$ . The rest is to show that $v^*(x)$ can be linearly represented by the vectors in $\mathcal{B}$ for any $x\in\Sigma^*$ . Let $x=x_jy$ for some $x_j$ and $y\in\Sigma^*$ . By induction on the length $|y|$ of y. If $|y|=0$ , i.e., $y=\varepsilon$ , then it is clear for $x=x_j$ . If $|y|=1$ , then due to the procedure of algorithm, $v^*(x_jy)$ is linearly dependent on $\mathcal{B}$ . Suppose that it holds for $|y|=k\geq 0$ . Then we need to verify it holds for $|y|=k+1$ . Denote $y=z\sigma$ with $|z|=k$ . Then with induction hypothesis we have $v^*(x_jz)= \sum_{k}c_kv^*(x_k)$ . Therefore, we have

(7) \begin{align}v^*(x)&=v^*(x_jz\sigma)\nonumber\\&=U(\sigma)v^*(x_jz)\nonumber\\&=U(\sigma)\sum_{k}c_kv^*(x_k)\nonumber\\&=\sum_{k}c_kv^*(x_k\sigma). \end{align}

Since $v^*(x_k\sigma)$ is linearly dependent on $\mathcal{B}$ for $k=1,2,\ldots,m$ , the proof is completed.

The purpose of Algorithm 1 is to learn the target MO-1QFA $\mathcal{M}=(Q, |\psi_0\rangle,\{U(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r)$ , so we need to verify $\mathcal{M}^*=(Q, |\psi_0^*\rangle,\{V(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r)$ obtained is equivalent to $\mathcal{M}$ . For this, it suffices to check $V(x)|\psi_0^*\rangle=U(x)|\psi_0\rangle$ for any $x\in\Sigma^*$ , where $V(x)=V(\sigma_s)V(\sigma_{s-1})\ldots V(\sigma_1)$ and $U(x)=U(\sigma_s)U(\sigma_{s-1})\ldots U(\sigma_1)$ for $x=\sigma_1\sigma_2\ldots\sigma_s$ .

Theorem 4. In Algorithm 1 for learning MO-1QFA, for any $x\in\Sigma^*$ ,

(8) \begin{equation} V(x)|\psi_0^*\rangle=U(x)|\psi_0\rangle. \end{equation}

Proof. For $x=\varepsilon$ , $V(\varepsilon)=U(\varepsilon)=I$ , and $|\psi_0^*\rangle={\boldsymbol{AD}}(\varepsilon)=|\psi_0\rangle$ , so it holds.

For any $\sigma\in\Sigma$ and for any $ v^*(x) \in \mathcal{B}$ , according to Algorithm 1, we have $\ V(\sigma)v^*(x)=v^*(x\sigma)={\boldsymbol{AD}}(x\sigma)$ . In particular, taking $x=\varepsilon$ , then we have $\ V(\sigma)|\psi_0^*\rangle=v^*(\sigma)={\boldsymbol{AD}}(\sigma)=U(x)|\psi_0\rangle$ .

Suppose it holds for $|x|= k$ . The rest is to prove that it holds for $|x|= k+1$ . Denote $y=x\sigma$ where $|x|= k$ and $\sigma\in\Sigma$ . Due to Proposition 4, $v^*(x)$ can be linearly represented by $\mathcal{B}=\{v^*(x_1), v^*(x_2),\ldots,v^*(x_m)\}$ , i.e., $v^*(x)=\sum_{k}c_kv^*(x_k)$ for some $c_k\in \mathbb{C}$ . With the induction hypothesis, $V(x)|\psi_0^*\rangle=U(x)|\psi_0\rangle$ holds. Then by means of Algorithm 1, we have

(9) \begin{align}V(y)|\psi_0^*\rangle &=V(x\sigma)|\psi_0^*\rangle \nonumber\\&=V(\sigma)V(x)|\psi_0^*\rangle \nonumber\\&=V(\sigma)U(x)|\psi_0\rangle \nonumber\\&=V(\sigma)v^*(x)\nonumber\\&=V(\sigma)\sum_{k}c_kv^*(x_k)\nonumber\\&=\sum_{k}c_kV(\sigma)v^*(x_k)\nonumber\\&=\sum_{k}c_kv^*(x_k\sigma). \end{align}

On the other hand, since $v^*(z)={\boldsymbol{AD}}(z)=U(z)|\psi_0\rangle$ for any $z\in \Sigma^*$ , we have

(10) \begin{align}\sum_{k}c_kv^*(x_k\sigma)&=\sum_{k}c_kU(x_k\sigma)|\psi_0\rangle\nonumber\\&=\sum_{k}c_kU(\sigma)U(x_k)|\psi_0\rangle\nonumber\\&=\sum_{k}c_kU(\sigma)v^*(x_k)\nonumber\\&=U(\sigma)\sum_{k}c_kv^*(x_k)\nonumber\\&=U(\sigma)v^*(x)\nonumber\\&=U(x\sigma)|\psi_0\rangle\nonumber \\&=U(y)|\psi_0\rangle. \end{align}

So, the proof is completed.

From Theorem 4, it follows that Algorithm 1 returns an equivalent MO-1QFA to the target MO-1QFA $\mathcal{M}=(Q, |\psi_0\rangle,\{U(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r)$ to be learned. Next we analyze the computational complexity of Algorithm 1.

Proposition 5. Let the target MO-1QFA to be learned have n’s bases states. The the computational complexity of Algorithm 1 is $O(n^5|\Sigma|)$ .

Proof. We consider it from two parts.

  • (I) The first part of Algorithm 1 to get $\mathcal{B}$ : The complexity to determine the linear independence of some n-dimensional vectors is $O(n^3)$ (Faddeev and Faddeev, Reference Faddeev and Faddeev1963), and there are at most n time to check this, so the first part of Algorithm 1 to get $\mathcal{B}$ needs time $O(n^4)$ .

  • (II) The second part of finding the feasible solutions for $V(\sigma)$ for each $\sigma\in\Sigma$ : For any $\sigma\in\Sigma$ , Step 15 defines $|\mathcal{B}|$ ’s matrix equations and these equations are clearly equivalent to a group of linear equations, but are subject to the restriction conditions in Step 16. So, this part is a problem of linear programming and we can refer to Boyd and Vandenberghe (Reference Boyd and Vandenberghe2004) and Karmarkar (Reference Karmarkar1984) to get the time complexity is $O(n^5|\Sigma|)$ .

Therefore, by combining (I) and (II) we have the complexity of Algorithm 1 is $O(n^5|\Sigma|)$ .

To illustrate Algorithm 1 for learning MO-1QFA, we give an example as follows.

Example 1. Suppose that $\mathcal{M}=(Q,|\psi_0\rangle,\{U(\sigma)\}_{\sigma\in\Sigma},Q_{a},Q_r)$ is an MO- ${\rm 1QFA} $ to be learned by Algorithm 1, where $Q=\{q_{0},q_{1}\}$ , $Q_a=\{q_{1}\}$ , $Q_r=\{q_{0}\}$ , $ \Sigma=\{a\}$ , $U(a)=\begin{bmatrix}\frac{1}{\sqrt{2}} & \frac{1}{\sqrt{2}}\\\frac{1}{\sqrt{2}} & -\frac{1}{\sqrt{2}}\\\end{bmatrix}$ , states $q_0$ and $q_1$ correspond to the two quantum basis states $|q_0\rangle=\begin{bmatrix}1\\0 \\\end{bmatrix}$ and $|q_1\rangle=\begin{bmatrix}0\\1 \\\end{bmatrix}$ , and $|\psi_0\rangle=|q_0\rangle$ . Denote $\mathcal{M}^*=(Q,|\psi_0\rangle^*,\{V(\sigma)\}_{\sigma\in\Sigma},Q_{a},Q_r)$ as the MO- ${\rm 1QFA} $ learned from Algorithm 1, and the procedure for obtaining $\mathcal{M}^*$ from Algorithm 1 is given below.

Step 1 of Algorithm 1 yields

(11) \begin{equation}\begin{split}|\psi_0\rangle^*=&\textbf{AD}(\epsilon)\\=&U(\epsilon)|\psi_0\rangle\\=&I|\psi_0\rangle\\=&|q_0\rangle.\end{split}\end{equation}

The 1st iteration run of the while loop body in Algorithm 1 is given below, with the computation of each set.

Step 6 of Algorithm 1 yields

(12) \begin{equation}\begin{split}v^*(\epsilon)=&\textbf{AD}(\epsilon)\\=&U(\epsilon)|\psi_0\rangle\\=&I|\psi_0\rangle\\=&|q_0\rangle.\end{split}\end{equation}

Step 8 of Algorithm 1 yields

(13) \begin{equation}\begin{split}Nod=\{node(a)\}.\end{split}\end{equation}

Step 9 of Algorithm 1 yields

(14) \begin{equation}\begin{split}\mathcal{B}=\{|q_0\rangle\}.\end{split}\end{equation}

The 2nd iteration run of the while loop body in Algorithm 1 is given below, with the computation of each set.

Step 6 of Algorithm 1 yields

(15) \begin{equation}\begin{split}v^*(a)=&\textbf{AD}(a)\\=&U(a)|\psi_0\rangle\\=&U(a)|q_0\rangle\\=&\frac{|q_0\rangle+|q_1\rangle}{\sqrt{2}}.\end{split}\end{equation}

Step 8 of Algorithm 1 yields

(16) \begin{equation}\begin{split}Nod=\{node(aa)\}.\end{split}\end{equation}

Step 9 of Algorithm 1 yields

(17) \begin{equation}\begin{split}\mathcal{B}=\left\{|q_0\rangle,\frac{|q_0\rangle+|q_1\rangle}{\sqrt{2}}\right\}.\end{split}\end{equation}

The 3rd iteration run of the while loop body in Algorithm 3 is given below, with the computation of each set.

Step 6 of Algorithm 1 yields

(18) \begin{equation}\begin{split}v^*(aa)=&\textbf{AD}(aa)\\=&U(aa)|\psi_0\rangle\\=&U(a)U(a)|q_0\rangle\\=&|q_0\rangle.\end{split}\end{equation}

Since $v^*(x)$ belongs to $span(\mathcal{B})$ , the statements in the branch statement are not executed at this point. The set Nod is the empty set at this point, so Algorithm 1 exits from the while loop body.

Finally, let $V(a)=\begin{bmatrix}x_{11}(a) & x_{12}(a) \\x_{21}(a) & x_{22}(a) \\\end{bmatrix}$ , and according to steps 15 and 16 of Algorithm 1, we get

(19) \begin{equation}\begin{split}V(a)v^*(\epsilon)=&V(a)|q_0\rangle\\=&v^*(a)\\=&\textbf{AD}(a)\\=&\frac{|q_0\rangle+|q_1\rangle}{\sqrt{2}}.\end{split}\end{equation}

(20) \begin{equation}\begin{split}V(a)v^*(a)=&V(a)\left(\frac{|q_0\rangle+|q_1\rangle}{\sqrt{2}}\right)\\=&v^*(aa)\\=&\textbf{AD}(aa)\\=&|q_0\rangle.\end{split}\end{equation}

From Eqs. (19) and (20), the following system of equations is obtained

(21) \begin{equation}\begin{cases}\begin{bmatrix}x_{11}(a) & x_{12}(a) \\x_{21}(a) & x_{22}(a) \\\end{bmatrix}\begin{bmatrix}1 \\0 \\\end{bmatrix}=\begin{bmatrix}\frac{1}{\sqrt{2}}\\\frac{1}{\sqrt{2}} \\\end{bmatrix},\\\begin{bmatrix}x_{11}(a) & x_{12}(a) \\x_{21}(a) & x_{22}(a) \\\end{bmatrix}\begin{bmatrix}\frac{1}{\sqrt{2}}\\\frac{1}{\sqrt{2}} \\\end{bmatrix}=\begin{bmatrix}1 \\0\\\end{bmatrix}.\end{cases}\end{equation}

Solving the system of Eq. (21) gives

(22) \begin{equation}\begin{split}V(a)=&\begin{bmatrix}x_{11}(a) & x_{12}(a) \\x_{21}(a) & x_{22}(a) \\\end{bmatrix}\\=&\begin{bmatrix}\frac{1}{\sqrt{2}} & \frac{1}{\sqrt{2}}\\\frac{1}{\sqrt{2}} & -\frac{1}{\sqrt{2}}\\\end{bmatrix}.\end{split}\end{equation}

As a result, we can obtain $\mathcal{M}^*=(Q,|\psi_0\rangle^*,\{V(\sigma)\}_{\sigma\in\Sigma},Q_{a},Q_r)$ , where $Q=\{q_{0},q_{1}\}$ , $|\psi_0\rangle^*=|q_0\rangle$ , $Q_a=\{q_{1}\}$ , $Q_r=\{q_{0}\}$ , $ \Sigma=\{a\}$ , and $V(a)=\begin{bmatrix}\frac{1}{\sqrt{2}} & \frac{1}{\sqrt{2}}\\\frac{1}{\sqrt{2}} & -\frac{1}{\sqrt{2}}\\\end{bmatrix}$ .

Therefore, the MO- ${\rm 1QFA} $ $\mathcal{M}^*$ , which is equivalent to MO- ${\rm 1QFA} $ $\mathcal{M}$ , can be obtained from Algorithm 1.

4. Learning MM-1QFA

In this section, we study learning MM-1QFA via ${\boldsymbol{AD}}$ oracle. Let $\mathcal{M}=(Q, |\psi_0\rangle, \{U(\sigma)\}_{\sigma\in \Gamma}, Q_a,Q_r,Q_g)$ be the target QFA to be learned, where $\Gamma=\Sigma\cup\{\$\}$ , and $\$\notin\Sigma$ is an end-maker. As usual, $Q, Q_a, Q_r, Q_g$ are supposed to be known, and the goal is to achieve unitary matrices $V(\sigma)$ for each $\sigma\in \Gamma$ in order to get an equivalent MM-1QFA $\mathcal{M}^*=(Q, |\psi_0^*\rangle, \{V(\sigma)\}_{\sigma\in \Gamma}, Q_a,Q_r,Q_g)$ . ${\boldsymbol{AD}}$ oracle can answer an amplitude distribution ${\boldsymbol{AD}}(x)$ for any $x\in\Gamma^*$ . MM-1QFA performs measuring after reading each input symbol, and then only the non-halting (i.e. going on) states continue to implement computing for next step, and the amplitude distribution for the superposition state after performing each unitary matrix needs to be learned from oracle.

Therefore, for any $x=\sigma_1\sigma_2\ldots\sigma_k\in\Gamma^*$ , since MM-1QFA $\mathcal{M}$ outputs the following state (un-normalized form) as the current state:

(23) \begin{equation}U(\sigma_k)P_nU(\sigma_{k-1})P_n\ldots U(\sigma_1)P_n|\psi_0\rangle,\end{equation}

we require ${\boldsymbol{AD}}$ oracle can answer ${\boldsymbol{AD}}(x)=U(\sigma_k)P_nU(\sigma_{k-1})P_n\ldots U(\sigma_1)P_n|\psi_0\rangle$ . In particular, ${\boldsymbol{AD}}(\varepsilon)=|\psi_0\rangle$ .

Before presenting the algorithm of learning MM-1QFA, we describe the main ideas and procedure.

First the initial state can be learned from ${\boldsymbol{AD}}$ oracle via querying empty string $\varepsilon$ .

Then by using ${\boldsymbol{AD}}$ oracle we are going to search for a base $\mathcal{B}$ of the Hilbert space spanned by $\{v^*(x): x\in\Sigma^*\}$ where for any $x=\sigma_1\sigma_2\ldots\sigma_k\in\Sigma^*$ ,

(24) \begin{equation}v^*(x)={\boldsymbol{AD}}(x)=U(\sigma_k)P_nU(\sigma_{k-1})P_n\ldots U(\sigma_1)P_n|\psi_0\rangle.\end{equation}

This procedure will be terminated due to the finite dimension of the space (at most $|Q|$ ), and this can be completed with polynomial time.

Finally, by combining the base $\mathcal{B}$ and with groups of linear equations we can obtain $V(\sigma)$ for each $\sigma\in\Sigma$ . These results can be verified in detail after Algorithm 2, and we now present Algorithm 2 for learning MM-1QFA in the following.

Algorithm 2 Algorithm for learning MM-1QFA $\mathcal{M}=(Q, |\psi_0\rangle, \{U(\sigma)\}_{\sigma\in \Gamma}, Q_a,Q_r,Q_g)$

Next we first demonstrate that the algorithm can find out a base $\mathcal{B}$ for Hilbert space $span\{v^*(x)| x\in\Sigma^*\}$ .

Proposition 6 In Algorithm 2 for learning MM-1QFA, the final set of vectors $\mathcal{B}$ consists of a base of Hilbert space $span\{v^*(x)| x\in\Sigma^*\}$ , where $v^*(x)$ is actually the vector replied by oracle ${\boldsymbol{AD}}$ for input string x, that is $v^*(x)={\boldsymbol{AD}}(x)=U(\sigma_k)P_nU(\sigma_{k-1})P_n\ldots U(\sigma_1)P_n|\psi_0\rangle$ , for $x=\sigma_1\sigma_2\ldots\sigma_k\in\Sigma^*$ .

Proof. Suppose that $\mathcal{B}=\{v^*(x_1), v^*(x_2),\ldots,v^*(x_m)\}$ , where it is clear that some $x_i$ equals to $\varepsilon$ . So, for any $x\in\Sigma^*$ , there are $x_j$ and $y\in\Sigma^*$ such that $x=x_jy$ . It suffices to show that $v^*(x)$ can be linearly represented by the vectors in $\mathcal{B}$ . By induction on the length $|y|$ of y. If $|y|=0$ , i.e., $y=\varepsilon$ , then it is obvious for $x=x_j$ . In addition, for $|y|=1$ , $v^*(x_jy)$ is linearly dependent on $\mathcal{B}$ in terms of the algorithm’s operation. Suppose that it holds for $|y|=k\geq 0$ . Then we need to verify it holds for $|y|=k+1$ . Denote $y=z\sigma$ with $|z|=k$ . Then by induction hypothesis $v^*(x_jz)= \sum_{k}c_kv^*(x_k)$ for some $c_k\in\mathbb{C}$ with $k=1,2,\ldots,m$ . Therefore, we have

(25) \begin{align}v^*(x)&=v^*(x_jz\sigma)\nonumber\\&=U(\sigma)P_nv^*(x_jz)\nonumber\\&=U(\sigma)P_n\sum_{k}c_kv^*(x_k)\nonumber\\&=\sum_{k}c_kU(\sigma)P_nv^*(x_k)\nonumber\\&=\sum_{k}c_kv^*(x_k\sigma). \end{align}

Since $v^*(x_k\sigma)$ is linearly dependent on $\mathcal{B}$ for $k=1,2,\ldots,m$ , $v^*(x)$ can be linearly represented by the vectors in $\mathcal{B}$ and the proof is completed.

Then we need to verify that the MM-1QFA $\mathcal{M}^*$ obtained in Algorithm 2 is equivalent to the target MM-1QFA $\mathcal{M}$ . This can be achieved by checking $V(\$)P_n|\psi_0^*\rangle=U(\$)P_n|\psi_0\rangle$ and for any $x=\sigma_1\sigma_2\ldots\sigma_k\in\Sigma^*$ ,

(26) \begin{equation}V(\sigma_k)P_nV(\sigma_{k-1})P_n\ldots V(\sigma_1)P_n|\psi_0^*\rangle=U(\sigma_k)P_nU(\sigma_{k-1})P_n\ldots U(\sigma_1)P_n|\psi_0\rangle.\end{equation}

So we are going to prove the following theorem.

Theorem 5. In Algorithm 2 for learning MM-1QFA, we have

(27) \begin{equation} V(\$)P_n|\psi_0^*\rangle=U(\$)P_n|\psi_0\rangle;\end{equation}

and for any $x=\sigma_1\sigma_2\ldots\sigma_k\in\Sigma^*$ , Eq. (26) holds, where $|x|\geq 1$ .

Proof. Note $ v^*(\varepsilon) \in \mathcal{B}$ , by means of Step 15 in Algorithm 2 and taking $\sigma=\$ $ , we have

(28) \begin{equation}V(\$)P_nv^*(\varepsilon)=v^*(\$)={\boldsymbol{AD}}(\$)=U(\$)P_n|\psi_0\rangle.\end{equation}

Since $ v^*(\varepsilon)={\boldsymbol{AD}}(\varepsilon)=|\psi_0\rangle$ , and from Algorithm 2 we know $ {\boldsymbol{AD}}(\varepsilon)=|\psi_0^*\rangle$ , Eq. (27) holds.

Next we prove that Eq. (26) holds for any $x=\sigma_1\sigma_2\ldots\sigma_k\in\Sigma^*$ . We do it by induction method on the length of $|x|$ .

If $|x|=1$ , say $x=\sigma\in\Sigma$ , then with Step 15 in Algorithm 2 and taking $v^*(\varepsilon)$ , we have $V(\sigma)P_nv^*(\varepsilon)=v^*(\sigma)={\boldsymbol{AD}}(\sigma)=U(\sigma)P_n|\psi_0\rangle$ , so, Eq. (26) holds for $|x|=1$ due to $v^*(\varepsilon)=|\psi_0\rangle$ .

Assume that Eq. (26) holds for any $|x|=k\geq 1$ . The rest is to prove that Eq. (26) holds for any $|x|=k+1$ . Let $x=y\sigma$ with $y=\sigma_1\sigma_2\ldots\sigma_k$ . Suppose $v^*(y)=\sum_{i}c_iv^*(x_i)$ for some $c_k\in \mathbb{C}$ . For each i, by means of Step 15 in Algorithm 2, we have

(29) \begin{equation}V(\sigma)P_nv^*(x_i)=v^*(x_i\sigma)={\boldsymbol{AD}}(x_i\sigma)=U(\sigma)P_n{\boldsymbol{AD}}(x_i),\end{equation}

and therefore

(30) \begin{equation}V(\sigma)P_n\sum_{i}c_iv^*(x_i)=U(\sigma)P_n\sum_{i}c_i{\boldsymbol{AD}}(x_i).\end{equation}

Since $v^*(x_i)={\boldsymbol{AD}}(x_i)$ , we further have

(31) \begin{equation}V(\sigma)P_nv^*(y)=U(\sigma)P_nv^*(y).\end{equation}

By using $v^*(y)=U(\sigma_k)P_nU(\sigma_{k-1})P_n\ldots U(\sigma_1)P_n|\psi_0\rangle$ , and the above induction hypothesis (i.e., Eq. (26) holds), we have

(32) \begin{equation}V(\sigma_{k+1})P_nV(\sigma_k)P_nV(\sigma_{k-1})P_n\ldots V(\sigma_1)P_n|\psi_0^*\rangle=U(\sigma_{k+1})P_nU(\sigma_{k-1})P_n\ldots U(\sigma_1)P_n|\psi_0\rangle.\end{equation}

Consequently, the proof is completed.

To conclude the section, we give the computational complexity of Algorithm 2.

Proposition 7. Let the target MM-1QFA to be learned have n’s bases states. Then the computational complexity of Algorithm 2 is $O(n^5|\Sigma|)$ .

Proof. It is actually similar to the proof of Proposition 5.

Remark 2. Weighted finite automata (WFA) (e.g., see Balle and Mohri (Reference Balle, Mohri and Maletti2015)) are finite automata whose transitions and states are augmented with some weights, elements of a semiring, and a WFA also induces a function over strings. Learning WFA has been significantly studied and the details can be referred to Balle and Mohri (Reference Balle, Mohri and Maletti2015) and the references therein. The algorithms for learning WFA are closely related to Hankel matrices. More specifically, for a field S and a finite alphabet $\Sigma$ , then the rank of the Hankel matrix $H_f$ associated with a function $f:\Sigma^*\rightarrow S$ is finite if and only if there exists a WFA $\mathcal{A }$ representing f with rank ( $H_f$ ) states and no WFA representing f admits fewer states. Though MQ and EQ are used in in the algorithms of learning WFA, the way to induce functions by WFA is different from the definitions of accepting probabilities in QFA, and particularly it is not known whether the Hankel matrices can be used to study QFA (as we are aware, there are no results concerning the Hankel matrices associated with QFA). Therefore, it is still an open problem of whether the algorithms of learning WFA can be used to study learning QFA.

5. Concluding Remarks

QFA are simple models of quantum computing with finite memory, but QFA have significant advantages over classical finite automata concerning state complexity (Ambainis and Yakaryilmaz, Reference Ambainis, Yakaryilmaz and Pin2021; Bhatia and Kumar, Reference Bhatia and Kumar2019; Say and Yakaryılmaz, 2014), and QFA can be realized physically to a considerable extent (Mereghetti et al., Reference Mereghetti, Palano and Cialdi2020). As a new topic in quantum learning theory and quantum machine learning, learning QFA via queries has been studied in this paper. As classical model learning (Vaandrager, Reference Vaandrager2017), we can term it as quantum model learning.

The main results we have obtained are that we have proposed two polynomial-query learning algorithms for measure-once one-way QFA (MO-1QFA) and measure-many one-way QFA (MM-1QFA), respectively. The oracle to be used is an ${\boldsymbol{AD}}$ oracle that can answer an amplitude distribution, and we have analyzed that a weaker oracle being only able to answer accepting or rejecting for any inputting string may be not enough for learning QFA with polynomial time.

Here a question is how to compare ${\boldsymbol{AD}}$ oracle with ${\boldsymbol{MQ}}$ oracle and ${\boldsymbol{EQ}}$ oracle? In general, ${\boldsymbol{MQ}}$ oracle and ${\boldsymbol{EQ}}$ oracle are together used in classical models learning with deterministic or nondeterministic transformation of states; ${\boldsymbol{AD}}$ oracle can return a superposition state for an input string in QFA, as ${\boldsymbol{SD}}$ oracle in Tzeng (Reference Tzeng1992) can return a distribution of state for an input string in PFA, so for learning DFA, ${\boldsymbol{AD}}$ oracle and ${\boldsymbol{SD}}$ oracle can return a state for each input string, not only accepting state as ${\boldsymbol{MQ}}$ oracle can do. Of course, the problem of whether both ${\boldsymbol{MQ}}$ oracle and ${\boldsymbol{EQ}}$ oracle together can be used to study QFA learning is still not clear. Furthermore, if ${\boldsymbol{AD}}$ oracle can return the weight of general weighted automata for each input string, then the problem of whether ${\boldsymbol{AD}}$ oracle can be used to study general weighted automata learning is worthy of consideration carefully.

However, we still do not know whether there is a weaker oracle $\mathcal{Q}$ than ${\boldsymbol{AD}}$ oracle but by using $\mathcal{Q}$ one can learn MO-1QFA or MM-1QFA with polynomial time. Furthermore, what is the weakest oracle to learn MO-1QFA and MM-1QFA with polynomial query complexity? These are interesting and challenging problems to be solved. Of course, for learning RFA, similar to learning DFA (Angluin, Reference Angluin1987), we can get an algorithm of polynomial time by using MQ together with EQ.

Another interesting problem is how to realize these query oracles physically, including ${\boldsymbol{SD}}$ oracle, ${\boldsymbol{AD}}$ oracle, and even ${\boldsymbol{MQ}}$ as well as ${\boldsymbol{EQ}}$ . In quantum query algorithms, for any given Boolean function f, it is supposed that a quantum query operator called an oracle, denoted by $O_f$ , can output the value of f(x) with any input x. As for the construction of quantum circuits for $O_f$ , there are two cases: (1) If a Boolean function f is in the form of disjunctive normal form and suppose that the truth table of f is known, then an algorithm for constructing quantum circuit to realize $O_f$ was proposed in Avron et al. (Reference Avron, Casper and Rozen2021). However, this method relies on the truth table of the function, which means that it is difficult to apply, since the truth table of the function is likely not known in practice. (2) If a Boolean function f is a conjunctive normal form, then a polynomial-time algorithm was designed in (Qiu et al., Reference Qiu, Luo and Xiao2022) for constructing a quantum circuit to realize $O_f$ , without any further condition on f.

As mentioned above, besides MO-1QFA and MM-1QFA, there are other one-way QFA, including Latvian QFA (Ambainis et al., Reference Ambainis, Beaudry, Golovkins, Kikusts, Mercer and Therien2006), QFA with control language (Bertoni et al., Reference Bertoni, Mereghetti and Palano2003), 1QFA with ancilla qubits (1QFA-A) (Paschen, Reference Paschen2000), one-way quantum finite automata together with classical states (1QFAC) (Qiu et al., Reference Qiu, Li, Mateus and Sernadas2015), and other 1QFA such as Nayak-1QFA (Na-1QFA), General-1QFA (G-1QFA), and fully 1QFA (Ci-1QFA). So, one of the further problems worthy of consideration is to investigate learning these QFA via queries.

Finally, we would like to analyze partial possible methods for considering these problems. In the present paper, we have used ${\boldsymbol{AD}}$ oracle as queries and quantum algorithms for determining the equivalence between 1QFA to be learned for learning both MO-1QFA and MM-1QFA. So, an algorithm for determining the equivalence between 1QFA to be learned is necessary in our method. In general, as we studied in Li and Qiu (Reference Li and Qiu2008), for designing an algorithm to determine the equivalence between 1QFA, we first transfer the 1QFA to a classical linear mathematical model, and then obtain the result by using the known algorithm for determining the equivalence between classical linear mathematical models. As pointed out in Ambainis and Yakaryilmaz (Reference Ambainis, Yakaryilmaz and Pin2021), the equivalence between 1QFA can be determined, though the equivalence problems for some of 1QFA still have not been studied carefully. Of course, some 1QFA also involve more parameters to be learned, for example, 1QFAC have classical states to be determined.

Acknowledgements

The authors are grateful to the two anonymous referees for invaluable suggestions and comments that greatly helped us improve the quality of this paper. This work was supported in part by the National Natural Science Foundation of China (Nos. 61876195, 61572532) and the Natural Science Foundation of Guangdong Province of China (No. 2017B030311011).

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Figure 0

Algorithm 1 Algorithm for learning MO-1QFA $\mathcal{M}=(Q, |\psi_0\rangle,\{U(\sigma)\}_{\sigma\in \Sigma}, Q_a,Q_r) $

Figure 1

Algorithm 2 Algorithm for learning MM-1QFA $\mathcal{M}=(Q, |\psi_0\rangle, \{U(\sigma)\}_{\sigma\in \Gamma}, Q_a,Q_r,Q_g)$