Quantum neural networks
- URL: http://arxiv.org/abs/2205.08154v1
- Date: Tue, 17 May 2022 07:47:00 GMT
- Title: Quantum neural networks
- Authors: Kerstin Beer
- Abstract summary: This thesis combines two of the most exciting research areas of the last decades: quantum computing and machine learning.
We introduce dissipative quantum neural networks (DQNNs), which are capable of universal quantum computation and have low memory requirements while training.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: This PhD thesis combines two of the most exciting research areas of the last
decades: quantum computing and machine learning. We introduce dissipative
quantum neural networks (DQNNs), which are designed for fully quantum learning
tasks, are capable of universal quantum computation and have low memory
requirements while training. These networks are optimised with training data
pairs in form of input and desired output states and therefore can be used for
characterising unknown or untrusted quantum devices. We not only demonstrate
the generalisation behaviour of DQNNs using classical simulations, but also
implement them successfully on actual quantum computers. To understand the
ultimate limits for such quantum machine learning methods, we discuss the
quantum no free lunch theorem, which describes a bound on the probability that
a quantum device, which can be modelled as a unitary process and is optimised
with quantum examples, gives an incorrect output for a random input. Moreover
we expand the area of applications of DQNNs in two directions. In the first
case, we include additional information beyond just the training data pairs:
since quantum devices are always structured, the resulting data is always
structured as well. We modify the DQNN's training algorithm such that knowledge
about the graph-structure of the training data pairs is included in the
training process and show that this can lead to better generalisation
behaviour. Both the original DQNN and the DQNN including graph structure are
trained with data pairs in order to characterise an underlying relation.
However, in the second extension of the algorithm we aim to learn
characteristics of a set of quantum states in order to extend it to quantum
states which have similar properties. Therefore we build a generative
adversarial model where two DQNNs, called the generator and discriminator, are
trained in a competitive way.
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