Friday, May 3, 2019

"You should be skeptical of current attempts to make a quantum computer that enhances artificial intelligence"

Tiernan Ray at ZD Net:

All that glitters is not quantum AI
Why hasn't the field of artificial intelligence created the equivalent of human intelligence? Is it because the problem, "artificial general intelligence," isn't well understood, or is it because we just need much faster computers, specifically quantum computers?

The latter view is the source of a vibrant field of research, "Quantum Machine Learning," or QML. 
But a bit of skepticism is warranted.

"We need to look through a skeptical eye at the idea that quantum makes things faster and therefore can make machine learning advances," says Jennifer Fernick, the head of research at NCC Group-North America, a cyber-security firm based in Manchester, U.K.
Fernick was a keynote speaker a week ago at the O'Reilly A.I. conference in New York. She sat down this week to tell ZDNet why she's skeptical about all the hype that's emerging in the pairing of quantum and A.I.

"Right now, if we look at work in QML, people are experimenting with things such as, could we build a Support Vector Machine (SVM) or a Boltzmann Machine — can we build these existing canonical machine learning models — in the quantum machine," observes Fernick. She is referring to two older models of machine learning that emerged in the 1980s and the 1990s, prior to today's deep learning systems.
 
Indeed, recent research by IBM has attempted to show that even today's simple quantum systems, such as a 2-qubit model, can theoretically go well beyond what "classical" computers using the flow of electrons can compute.  

The IBM work is part of a recent craze to find uses for quantum computing before large systems are commercially viable. The trends is known as "shallow quantum circuits," also referred to as "Noisy Intermediate-Scale Quantum Devices," or "NISQ."

However, attempts in NISQ to speed up a shallow machine learning task, such as SVM or Boltzmann Machines, may not really be achieving much, she reflected. 

"Quantum computing can make certain things faster if the underlying math has a structure that is exploitable via quantum and we have the right quantum algorithms," she says. "Before we jump on the bandwagon, we need to ask, What are the true algorithmic innovations?" 
In the case of cryptography, one of Fernick's areas of focus as a security specialist, quantum computing is "clearly worth it," she says. 

A quantum computer can render trivial the operation of "factoring" a given number into its component prime numbers where a classical computer would find it impossible....
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