Metadata-Version: 2.1
Name: BraAndKet
Version: 0.6.0
Summary: BraAndKet is a library for numeral calculations of discrete quantum systems.
Home-page: https://github.com/ZhengKeli/BraAndKet
Author: Zheng Keli
Author-email: zhengkeli2009@126.com
License: UNKNOWN
Platform: UNKNOWN
Classifier: Programming Language :: Python :: 3
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: OS Independent
Requires-Python: >=3.6
Description-Content-Type: text/markdown

# BraAndKet

BraAndKet is a library for numeral calculations of discrete quantum systems.

# Quickstart

## Before Using

Please notice that this library is still actively developing. The stability and compatibility of APIs are **NOT** guaranteed. Breaking changes are happening every day! Using this library right now, you may take your own risk.

## Installation

You can install the latest release from [PiPy](https://pypi.org/project/BraAndKet/).

```shell
pip install braandket
```

Then you can import this library with name `bnk`

```python
import bnk
```

## KetSpace

Any quantum states can exist in some space called _Hilbert space_. You can use `bnk.KetSpace(n)` to define such a space, where `n` is its dimension. For example, to create a Hilbert space of a q-bit:

```python
qbit = bnk.KetSpace(2)
print(qbit)  # output: KetSpace(2)
```

You can define a name for a space using named parameter. The name is to describe this space when debugging. The name can
be a `str`, or any object to be printed out. When printed, the name of space will be shown, which is very helpful when debugging.

```python
qbit_a = bnk.KetSpace(2, name="a")
print(qbit_a)  # output: KetSpace(2, name=a)

qbit_b = bnk.KetSpace(2, name="b")
print(qbit_b)  # output: KetSpace(2, name=b)
```

You can call these 4 methods on a `KetSpace` instance to create ket vectors and operators:
* method `.eigenstate(k)` - to get a ket vector, representing the k-th eigenstate ![](https://latex.codecogs.com/svg.latex?|k\\rangle)
* method `.identity()` - to get an identity operator ![](https://latex.codecogs.com/svg.latex?I) in this Hilbert space
* method `.operator(k,b)` - to get an operator ![](https://latex.codecogs.com/svg.latex?|k\\rangle\\langle%20b|)
* method `.projector(k)` - to get a projector ![](https://latex.codecogs.com/svg.latex?|k\\rangle\\langle%20k|)

```python
ket_space = bnk.KetSpace(2)

ket_vec = ket_space.eigenstate(0)
identity_op = ket_space.identity()
increase_op = ket_space.operator(1, 0)
zero_proj = ket_space.projector(0)
```

A `KetSpace` is accompanied by a `BraSpace`. You can conveniently get it with `.ct` property. To avoid confusion, is not allowed to create any vectors or operations with a `BraSpace`. Please do so with its corresponding `KetSpace`. Calling `.ct` property, you can get back its `KetSpace`.

```python
ket_space = bnk.KetSpace(2)
print(ket_space)  # output: KetSpace(2)

bra_space = ket_space.ct
print(bra_space)  # output: BraSpace(2)

print(bra_space.ct is ket_space)  # output: True
```

## QTensors

`QTensor` is the basic type of computing elements in this library. A `QTensor` instance holds an `np.ndarray` as its values and a tuple of `Space` instances. Each `Space` corresponds to an axis of the `np.ndarray`. 

Any vectors, operators and tensors in quantum world are represented by `QTensor`. All vectors and operators mentioned above are all `QTensor` instances.

```python
ket_space = bnk.KetSpace(2)

ket_vec = ket_space.eigenstate(0)
print(ket_vec)  
# output: QTensor(spaces=(KetSpace(2),), values=[1. 0.])

identity_op = ket_space.identity()
print(identity_op)
# output: QTensor(spaces=(KetSpace(2), BraSpace(2)), values=[[1. 0.] [0. 1.]])

increase_op = ket_space.operator(1, 0)
print(increase_op) 
# output: QTensor(spaces=(KetSpace(2), BraSpace(2)), values=[[0. 0.] [1. 0.]])

zero_proj = ket_space.projector(0)
print(zero_proj)
# output: QTensor(spaces=(KetSpace(2), BraSpace(2)), values=[[1. 0.] [0. 0.]])
```

You can easily get a conjugate transposed `QTensor` calling `.ct` property. It should be noted that sometimes, such operation does not affect the values, but spaces.

```python
ket_space = bnk.KetSpace(2)

ket_vec = ket_space.eigenstate(0)
bra_vec = ket_vec.ct
print(bra_vec)  
# output: QTensor(spaces=(BraSpace(2),), values=[1. 0.])

increase_op = ket_space.operator(1, 0)
decrease_op = increase_op.ct
print(decrease_op) 
# output: QTensor(spaces=(BraSpace(2), KetSpace(2)), values=[[0. 0.] [1. 0.]])
```

`QTensor` instances can take tensor product using `@` operator. They can automatically inspect which spaces to be performed the "product-sum" (when the bra on the left meets the matching ket on the right), which to be remained.

### Example1: 
![](https://latex.codecogs.com/svg.latex?\\langle0|\\cdot|1\\rangle=\\langle0|1\\rangle=0)

```python
qbit = bnk.KetSpace(2)

amp = qbit.eigenstate(0).ct @ qbit.eigenstate(1)
print(amp)
# output: QTensor(spaces=(), values=0.0)
```

### Example2: 
![](https://latex.codecogs.com/svg.latex?|0\\rangle_a\\cdot|1\\rangle_b=|0\\rangle_a|1\\rangle_b)

```python
qbit_a = bnk.KetSpace(2, name="a")
qbit_b = bnk.KetSpace(2, name="b")

ket_vec_ab = qbit_a.eigenstate(0) @ qbit_b.eigenstate(1)
print(ket_vec_ab)
# output: QTensor(spaces=(KetSpace(2, name=a), KetSpace(2, name=b)), values=[[0. 1.] [0. 0.]])
```

### Example3: 
![](https://latex.codecogs.com/svg.latex?\\langle0|_a\\cdot|1\\rangle_b=\\langle0|_a|1\\rangle_b)

```python
qbit_a = bnk.KetSpace(2, name="a")
qbit_b = bnk.KetSpace(2, name="b")

tensor_ab = qbit_a.eigenstate(0).ct @ qbit_b.eigenstate(1)
print(tensor_ab)
# output: QTensor(spaces=(BraSpace(2, name=a), KetSpace(2, name=b)), values=[[0. 1.] [0. 0.]])
```

### Example4: 
![](https://latex.codecogs.com/svg.latex?A_%7Binc%7D%3D%5Cleft%20%7C%201%20%5Cright%20%5Crangle%20%5Cleft%20%5Clangle%200%20%5Cright%20%7C%20%3D%20%5Cbegin%7Bpmatrix%7D%200%20%26%200%5C%5C%201%20%26%200%20%5Cend%7Bpmatrix%7D)

![](https://latex.codecogs.com/svg.latex?A_{inc}|0\\rangle=|1\\rangle)

```python
qbit = bnk.KetSpace(2)

ket_vec_0 = qbit.eigenstate(0)
ket_vec_1 = qbit.eigenstate(1)
increase_op = qbit.operator(1, 0)
result = increase_op @ ket_vec_0

print(result)
# output: QTensor(spaces=(KetSpace(2),), values=[0. 1.])

print(result == ket_vec_1)
# output: True

```

(todo ...)

## Reduction

Sometimes, the space of system can be terribly big, since the space increases exponentially with the increase of the count of components.

But in some cases, we just want to study the evolution of the system under certain conditions, for example from several specified start points evolves with some certain operators. Then, some states are in fact impossible to be reached. Then those unreachable states can be dropped out of the computation. Class `ReducedKetSpace` is designed for such cases.

The static method `ReducedKetSpace.from_seed()` can automatically detect which eigenstates can be dropped, with the given starting states and evolution operators, and return an instance of `ReducedKetSpace` as a "reachable" space. This can significantly reduce the calculation and memory consumption.

The reduced and original tensors can also be easily converted to each other using method `reduce()` and `inflate()`.

## Evolve functions

(todo ...)

# Contribution

This library is completely open source. Any contributions are welcomed. You can fork this repository, make some useful changes and then send a pull request to me on GitHub.

