Towards a Distributed Quantum Computing Ecosystem (Invited Paper)

Towards a Distributed Quantum Computing Ecosystem (Invited Paper)

Towards a Distributed Quantum Computing Ecosystem (Invited Paper) Daniele Cuomo Marcello Caleffi Angela Sara Cacciapuoti University of Naples Federico II University of Naples Federico II University of Naples Federico II [email protected] marcello.caleffi@unina.it [email protected] Abstract—The Quantum Internet, by enabling quantum com- Sycamore, by sampling from the output distribution of 53- munications among remote quantum nodes, is a network capable qubits random quantum circuits [11]. By neglecting some of supporting functionalities with no direct counterpart in the performance-enhancing techniques as pointed out by IBM classical world. Indeed, with the network and communications functionalities provided by the Quantum Internet, remote quan- [12], [13], Google estimated that “a state-of-the-art supercom- tum devices can communicate and cooperate for solving chal- puter would require approximately 10,000 years to perform the lenging computational tasks by adopting a distributed computing equivalent task” that required just 200 seconds on Sycamore. approach. The aim of this paper is to provide the reader with an By ignoring the noise effects and by coarsely oversimpli- overview about the main challenges and open problems arising fying, the computing power of a quantum computer scales with the design of a Distributed Quantum Computing ecosystem. For this, we provide a survey, following a bottom-up approach, exponentially with the number of qubits that can be embedded from a communications engineering perspective. We start by and interconnected within [2]. And one of the reasons lays introducing the Quantum Internet as the fundamental underlying in a principle of quantum mechanics known as superposition infrastructure of the Distributed Quantum Computing ecosystem. principle. Specifically, a classical bit encodes one of two Then we go further, by elaborating on a high-level system mutually exclusive states - usually denoted as 0 and 1 - being abstraction of the Distributed Quantum Computing ecosystem. Such an abstraction is described through a set of logical layers. in only one state at a certain time. Conversely, a qubit can be Thereby, we clarify dependencies among the aforementioned in an extra mode - called superposition i.e., it can be in a layers and, at the same time, a road-map emerges. combination of the two basic states [2], [3]. Hence – thanks to the superposition principle – a qubit I. INTRODUCTION offers richer opportunities for carrying information and com- Nowadays, a tremendous amount of heterogeneous players puting, since it can do more than just flipping between 0 and entered the quantum race, ranging from tech giants - such as 1. And this quantum advantage grows exponentially with the IBM and Google in fierce competition to build a commercial number of qubits. In fact, while n classical bits are only in quantum computer - to states and governments, with massive one of the 2n possible states at any given moment, an n-qubit public funds to be distributed over the next years [1], [2], [3], register can be in a superposition of all the 2n possible states. [4]. To give a flavor of the above, let us consider one of In 2017, the European Commission launched a e1-billion the killer applications of the quantum computing: chemical flagship program to support the quantum research for ten years reaction simulation [14]. As highlighted in [15], the amount of starting from 2018, and a first e132-million tranche is being information needed to fully describe the energy configurations provided during the following three years [5]. In 2018, the of a relatively simple molecule such as caffeine is astoundingly United States of America launched the National Quantum large: 1048 bits. For comparison, the number of atoms in Initiative funded with $1.2-billion over ten years and China the Earth is estimated between 1049 and 1050 bits. Hence, is keeping up, investing billions to commercialize quantum describing the energy configuration of caffeine at one single technologies [6]. instant needs roughly a number of bits comparable to 1 to These huge efforts are justified by the disruptive potential 10 per cent of all the atoms on the planet. But this energy of a quantum computer, beyond anything classical computers arXiv:2002.11808v2 [quant-ph] 28 Mar 2020 configuration description becomes suddenly feasible with a could ever achieve. Indeed, by exploiting the rules of quantum quantum processor embedding roughly 160 noiseless qubits, mechanics, a quantum computer can tackle classes of problems thanks to the superposition principle. that choke conventional machines. These problems include Unfortunately, qubits are very fragile and easily modified by chemical reaction simulations, optimization in manufacturing interactions with the outside world, via a noise process known and supply chains, financial modeling, machine learning and as decoherence [16], [3]. Indeed, decoherence is not the only enhanced security [7], [8], [9]. Hence, the quantum computing source of errors in quantum computing. Errors practically arise has the potential to completely change markets and industries. with any operation on a quantum state. However, isolating At the end of 2019, Google achieved the so-called quan- the qubits from the surrounding is not the solution, since tum supremacy1 with a 54-qubits quantum processor, named the qubits must be manipulated to fulfill the communication and computing needs, such as reading/writing operations. 1The term was coined by J. Preskill in 2012 [10] to describe the moment when a programmable quantum device would solve a problem that cannot be Moreover, the challenges for controlling and preserving the solved by classical computers, regardless of the usefulness of the problem. quantum information embedded in a single qubit get harder as the number of qubits within a single device increases, due to coupling effects. In this regard, Quantum Error Cor- rection (QEC) represents a fundamental tool for protecting quantum information from noise and faulty operations [17], [18]. However, QEC operates by spreading the information of one logical qubit into several physical qubits. Hence, solving problems of practical interest, such as integer factorization – which constitutes one of the most widely adopted algorithms for securing communications over the current Internet – or molecule design may require millions of physical qubits [6], [7]. Hence, on one hand researchers worldwide are leveraging on the advancement of different technologies for qubit imple- mentation superconducting circuits, ion traps, quantum dots, and diamond vacancies among the others and innovative QEC techniques to scale the number of qubits beyond two-digits. On the other hand, the Quantum Internet, i.e., a network enabling Fig. 1. Distributed Quantum Computing speed-up. The volume of cubes quantum communications among remote quantum nodes, has represents the ideal quantum computing power, i.e., in absence of noise been recently proposed as the key strategy to significantly scale and errors. As evident by comparing the power available at isolated devices up the number of qubits [19], [20], [1], [21], [22]. versus the power achievable through clustered devices, the interconnection of quantum processors via the Quantum Internet provides an exponential In fact, the availability of such a network and the adoption computing speed-up with respect to isolated devices. of a distributed computing paradigm allows us to regard the Quantum Internet jointly as a virtual quantum computer with a number of qubits that scales linearly with the number of network2 able to transmit qubits and to distribute entangled interconnected devices. quantum states3 among remote quantum devices [3], [1], [2], In this light, the aim of this paper is to provide the [19], [20], [21], [23]. reader with an overview about the main challenges and open In fact,the availability of the corresponding underlying problems arising with the design of a Distributed Quantum network infrastructure and the adoption of the distributed Computing ecosystem. quantum computing paradigm [25] allows us to regard the We start in Sec. II by introducing the Quantum Internet – Quantum Internet – jointly – as a virtual quantum computer as the fundamental underlying communication infrastructure with a number of qubits that scales linearly with the number of a Distributed Quantum Computing ecosystem – as well as of interconnected devices. Hence, the Quantum Internet may some of its unique key applications. Then we go further in enable an exponential speed-up [26], [25], [1] of the quan- Sec. III, by conceptualizing a high-level system abstraction tum computing power with just a linear amount of physical of the Distributed Quantum Computing ecosystem from a resources, represented by the interconnected quantum proces- communication engineering perspective. Such an abstraction sors. Indeed, by comparing the computing power achievable is described through a set of (logical) layers, with the higher with quantum devices working independently versus working depending on the functionalities provided by the lower ones. as a unique quantum cluster, the gap comes out - as depicted Thereby, we clarify dependencies among the aforementioned in Fig. 1 [1]. layers. Since, each layer of the ecosystem has some related Specifically, increasing the number of isolated devices lays open challenges, within Sec. IV we survey such challenges to a linear speed-up, with a double growth in computational and open problems. Finally, in Sec. V

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