quantum computing and its applications · 2018-12-03 · •quantum computers alone are not...

Quantum Computing and Its Applications

Jia Jie NgohAdvisor : Prof. William J. Song

Overview• Introduction• Background

• Quantum Bits and Gates• Qubit Measurement• Experiment Environment

• Applications: Quantum Fourier Transform• Conclusion

Introduction• It becomes more challenging to drive the performance growth of

computing systems in conventional approaches, i.e., Moore’s Law.

• Quantum computing draws growing attention as an alternative solution to overcome the physical limitations of traditional computing systems and methods.

“How do quantum algorithms compare to classical computational methods?”

Quantum Bits• A quantum bit (or qubit) represents a datum in quantum computing.

• As opposed to a classical bit that can only be 0 or 1, the qubit stores the superposition status of 0 and 1 as follows.

| ⟩# = %| ⟩0 + (| ⟩1

| ⟩# = *+, -2 | ⟩0 + /01,23 -2 | ⟩1Bloch Sphere representation of a qubit:

Quantum Gates

Types Unitary Transform Functions

X gate 0 11 0 Bit flipping

Hadamard gate121 11 −1 Superposition

Controlled-NOT (CNOT)1 00 1

0 00 0

0 11 0

Controlling target qubit

• Quantum gates are used to manipulate qubits.Examples of Commonly Used Quantum Gates

Qubit Measurement• The observation of a qubit results in logical bits, 0 and 1, despite

its quantum property, e.g., superposition.• The observed result must be either 0 or 1 with the probability of

! " or # ", respectively; ! " + # " = 1.• Reading qubits inevitably incurs measurement errors.

Types Description

Gate error Errors occur in quantum gates, due to noise interference, e.g., Pauli error, thermal relaxation.

Readout error Errors occur in the process of probing qubits to determine its logical state.

Results of Measuring Qubit• There are two possible outcomes from measuring qubit, ideal

measurement (no errors) and real measurement (with errors).

abilitie

Output

abilitie

Output

(a) Ideal measurement (b) Real measurement

Experiment Environment• IBM provides public-use of cloud-based quantum computing

through online platform called IBM Q Experience.• Quantum programs are coded using Python in Qiskit, an open-

source quantum computing framework and then executed in real quantum processors.

Quantum programming Program offloading

User QiskitQuantum ProcessorResults report

Complexity of Quantum Fourier Transform• Quantum Fourier Transform (QFT) has the complexity of O(n2)

compared to O(n2n) of Fast Fourier Transform (FFT).• A function f(x) can be evaluated for many different values of x

simultaneously for QFT owing to quantum parallelism.

O(2#(∑%&'() *%. ,%)) = / 2# ∑%&'# 2= /(02#)

#(#1')2 operationsarerequired =O(n2)

Derivation of QFT Quantum Circuit

| ⟩# → 12' (

,-./012,341)/,-| ⟩6 = | ⟩0 +2,34+.1-| ⟩1 | ⟩0 +2,34+.1-;<1-| ⟩1 … | ⟩0 +2,34+.1<1>…1-| ⟩1

• QFT quantum circuit is built based on the equation below.

Quantum circuit representation of QFT algorithm

Code of QFT

(a) QFT program (b) Error modeling in Qiskitdef input_state(circuit, q, n):

#n-qubit input state for QFT that produces output 1s string

for j in range(n):circuit.h(q[j])circuit.u1(math.pi/float(2**(j)), q[j])

def qft(circuit, q, n):#n-qubit Quantum Fourier Transform on

qubits in circuitfor j in range(n):

for k in range(j):circuit.cu1(math.pi/float(2**(j-

k)), q[j], q[k])circuit.h(q[j])

z = 0.995004165 + 1j * 0.099833417z = z / abs(z)u_error = np.array([[1, 0], [0, z]])simulator_config = {“noise_params”:

{‘gate_time’: 0.00545,‘p_depol’: 0.001,‘p_pauli’: [0, 0, 0.01],‘U_error’: u_error,‘readout_error’: 0.0620

• The following codes create quantum program of QFT.

Scalability of QFT – 9 qubits

• Below is the result of running QFT circuit for 9 qubits.

0.00.20.40.60.81.0

abilitie

Output

(a) Real measurement

Quantum Circuit of 9 qubits QFT• Below is the generated quantum circuit of QFT for 9 qubits.• IBM Q Experience supports up to 32 qubits, but Qiskit GUI can

handle only a handful number of qubits.

QFT Extension: Shor’s Algorithm

• Below is the generated quantum circuit of Shor’s Algorithm.

Result of running Shor’s Algorithm

(a) Ideal measurement (b) Real measurement

• Below is the result of running Shor’s Algorithm for 5 qubits.

1.00000

abilitie

Output

abilitie

Output

Conclusion• Quantum computers alone are not sufficient to completely replace

traditional computing systems.

• However, they may significantly reduce computational complexity for particular algorithms (e.g., Quantum Fourier Transform) and hence can be used as accelerators, i.e., Quantum Accelerator.

• The current limitations of quantum processors lie in reliability, scalability, and programmability support.

References1) "IBM Q Experience", Quantumexperience.ng.bluemix.net, 2018.

[Online]. Available: https://quantumexperience.ng.bluemix.net/qx/experience. [Accessed: 11- Oct- 2018].

2) M. A. Nielsen and I. L. Chuang, Quantum Computation and Quantum Information, 10th ed. Cambridge University Press, 2010.

3) Monz, T., Nigg, D., Martinez, E., Brandl, M., Schindler, P., Rines, R., Wang, S., Chuang, I. and Blatt, R. (2016). Realization of a scalable Shor algorithm. Science, 351(6277), pp.1068-1070.

quantum computing and its applications · 2018-12-03 · •quantum computers alone are not...

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