Quick Overview

For quick start, please note 3 inputs. We we will name them: 1st, 2nd and 3rd — from left to right. Please also note 2 buttons: Run and Load.

1st input - init state

You enter init state of qubits here. Decimal integer is required here. Its binary representation defines start states of qubits in qregister. Qubit 0 is on the top.

2nd input - qubit signature

You enter list of integers here in the following format: [qubit1, qubit2, ..., qubitn]. This qubit signature is used for displaying probabilities.

Assume you entered here [3,4] and assume that list of probabilies is like the following:

01 : 0.3 (1)
10 : 0.7 (2)

It simply means that a lot of hypothetical measurements would show that Prob(qubit 4 is in state 0 AND qubit 3 is in state 1) = 0.3 and Prob(qubit 4 is in state 1 AND qubit 3 is in state 0) = 0.7.

Formally, the result is a list of integers with given probability. The n-th bit of chosen integer (from right) represents the state of quibit which is listed as n-th in qubit signature (from left) after hypothetical measurment. Note that you have these integer in binary and in decimal in ().

The same result for signature [4,3] would be obviously

01 : 0.7 (1)
10 : 0.3 (2)

3rd input - quantum circuit

You enter a list of quantum gates here in the following format [gate1, gate2, ..., gaten]. You can also add measurments to this list, they are represented by M(.).

Run Button

Ok, after you've entered initial state (if you don't the default state is 0) and qunatum circuit you press button Run, which applies quantum circuit to qregister and displays end state and probabilities after hypothetical measurement of qubits listed in qubit signature (2nd input). Like the following:

01 : 0.5 (1)
10 : 0.5 (2)

(0.707106781187,0)|1>
(0.707106781187,0)|2>

The first list are probabilities described in 2nd input - qubit signature section. The second list is just a state of quregister (a complex vector).

Load Button

When you create some more complex and long circuit you want to have it in saved text file. You can. Write your circuit in text file using your favorite editor, save it on your drive and then just press Load to load circuit to Quantum Simulator.

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Specification

Supported gates

H(bit) [Hadamard Gate]

Defined on base vectors $|[bit]\rangle$ :

$H|0\rangle = \frac{1}{\sqrt{2}}(|0\rangle + |1\rangle)$

$H|1\rangle = \frac{1}{\sqrt{2}}(|0\rangle - |1\rangle)$

X(bit) [Pauli X-gate]

Defined on base vectors $|[bit]\rangle$ :

$X|0\rangle = |1\rangle$

$X|1\rangle = |0\rangle$

Y(bit) [Pauli Y-gate]

Defined on base vectors $|[bit]\rangle$ :

$X|0\rangle = i|1\rangle$

$X|1\rangle = -i|0\rangle$

Z(bit) [Pauli Z-gate]

Defined on base vectors $|[bit]\rangle$ :

$X|0\rangle = |0\rangle$

$X|1\rangle = -|1\rangle$

R(n, bit) [Phase Shift Gate]

Defined on base vectors $|[bit]\rangle$ :

$R_n|0\rangle = |0\rangle$

$R_n|1\rangle = e^{i\pi/2^n}|1\rangle$

CNot(control, bit) [Controled Not Gate]

Defined on base vectors $|[control][bit]\rangle$ :

$CNot|00\rangle = |00\rangle$

$CNot|01\rangle = |01\rangle$

$CNot|10\rangle = |11\rangle$

$CNot|11\rangle = |10\rangle$

CCNot(control1, control2, bit) [Toffoli Gate]

Defined on base vectors $|[control1][control2][bit]\rangle$ :

$CCNot(|c_1c_2b>) = |c_1c_2(c_1\cdot c_2\oplus b)\rangle$

C(control, gate) [Universal Control Gate]

Defined on base vectors $|[control]x\rangle$ :

$C(gate)(|0\rangle|x\rangle) = |0\rangle|x\rangle$

$C(gate)(|1\rangle|x\rangle) = |0\rangle gate|x\rangle$

U([argbit₀, ...,argbit_n],[valbit₀, ...,valbit_m], function) [Universal Function Gate]

Defined on base vectors $|[argbit_n]\dots[argbit_0]\rangle|[valbit_m]\dots[valbit_0]\rangle$ :

$U_{function}|x\rangle|y\rangle = |x\rangle|y \oplus function(x)\rangle$

Hidden Console

jQ has additional advanced feature — Hidden Console. When you place cursor in the last file of the black window in the left you can enter some special directives. Bellow you will find a full list of Hidden Console directives:

JQ Manual

Contents

Quick Overview

1st input - init state

2nd input - qubit signature

3rd input - quantum circuit

Run Button

Load Button

Specification

Supported gates

H(bit) [Hadamard Gate]

X(bit) [Pauli X-gate]

Y(bit) [Pauli Y-gate]

Z(bit) [Pauli Z-gate]

R(n, bit) [Phase Shift Gate]

CNot(control, bit) [Controled Not Gate]

CCNot(control1, control2, bit) [Toffoli Gate]

C(control, gate) [Universal Control Gate]

U([argbit₀, ...,argbit_n],[valbit₀, ...,valbit_m], function) [Universal Function Gate]

Hidden Console

prob([signature₁, signature₂, ..., signature_n])

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Variants

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JQ Manual

Contents

Quick Overview

1st input - init state

2nd input - qubit signature

3rd input - quantum circuit

Run Button

Load Button

Specification

Supported gates

H(bit) [Hadamard Gate]

X(bit) [Pauli X-gate]

Y(bit) [Pauli Y-gate]

Z(bit) [Pauli Z-gate]

R(n, bit) [Phase Shift Gate]

CNot(control, bit) [Controled Not Gate]

CCNot(control1, control2, bit) [Toffoli Gate]

C(control, gate) [Universal Control Gate]

U([argbit0, ...,argbitn],[valbit0, ...,valbitm], function) [Universal Function Gate]

Hidden Console

prob([signature1, signature2, ..., signaturen])

Personal tools

Namespaces

Variants

Views

Actions

Search

Navigation

Toolbox

U([argbit₀, ...,argbit_n],[valbit₀, ...,valbit_m], function) [Universal Function Gate]

prob([signature₁, signature₂, ..., signature_n])