Quantized Celebrity

I’m sure all of you are well aware of the fact that Carmen Electra recently split up with Dave Navarro. Oh, what? You’re not? And why am I bringing this up? Check out this article. You’ve got wade down to the last paragraph. Okay I’ll wade for you:

In other Electra news in the notable quotables from Star Pulse Carmen drops this wonder:
“I’m really into quantum physics. Some of my friends are into it, some of them aren’t, so I’m trying to get them excited about discovering all these interesting things about thoughts and the power of thoughts.”
“It gives me chills thinking about it. It’s fun.”

Well, okay, I’m pretty sure that “the power of thoughts” and “quantum physics” is Deepak Chopra nonsense, but on the other hand, I’m happy that I share in common with Carmen Electra the belief that thinking about quantum physics is fun.

We can dance if we want to…

…We can leave your friends behind. ‘Cause your friends don’t dance and if they don’t dance, well they’re no friends of mine.
Yep, that’s right, it’s the new paper dance! In last weeks arxiv listing a new paper by myself and Andrea Cassacino, a graduate student from Siena, Italy, appeared as quant-ph/0610088:

Quantum Error Correcting Subsystem Codes From Two Classical Linear Codes
Authors: Dave Bacon, Andrea Cassacino
Comments: 8 pages, Allerton 2006 conference
The essential insight of quantum error correction was that quantum information can be protected by suitably encoding this quantum information across multiple independently erred quantum systems. Recently it was realized that, since the most general method for encoding quantum information is to encode it into a subsystem, there exists a novel form of quantum error correction beyond the traditional quantum error correcting subspace codes. These new quantum error correcting subsystem codes differ from subspace codes in that their quantum correcting routines can be considerably simpler than related subspace codes. Here we present a class of quantum error correcting subsystem codes constructed from two classical linear codes. These codes are the subsystem versions of the quantum error correcting subspace codes which are generalizations of Shor’s original quantum error correcting subspace codes. For every Shor-type code, the codes we present give a considerable savings in the number of stabilizer measurements needed in their error recovery routines.

The cool thing about this paper is that it officially makes me old. Why? Because now when you click on my name on the arxiv, I now have a second page of listings. Old as the hills, I say!

Interference of the Nonfootball Kind

Interference can occur in both classical and quantum systems. In the classical world we are well acclimatized to thinking of water waves or electromagnetic waves or slinky waves interfering. In the quantum world interference plays a particularly central role, as we learn that we can at best calculate the amplitudes of events and constructive and destructive interference is essential in understanding the speedups of quantum algorithms. The difference between the classical world and the quantum world cannot just be summed up to “interference.” However it is also clear that interference is an essential difference between quantum computers and probabilistic classical computers. So understading interference seems to be an important task for thinking about quantum algorithms.
But when we think about interference in a classical world, my picture is almost always a picture with classical wave equations. Is there a simple computer sciencish model which shows interference which isn’t based on wave equations or some other “physical” wave? Here is one such example.
Consider the quintisential quantum interference experiment. Start a single qubit in the state [tex]$|0rangle$[/tex]. Now if we apply the Hadmard transform [tex]$frac{1}{sqrt{2}}left[ begin{array}{cc} 1 & 1 \ 1 & -1 end{array}right]$[/tex] to this qubit, we now have the state [tex]$frac{1}{sqrt{2}}(|0rangle+|1rangle)$[/tex]. Measurement of this state would then result in 50 percent probability of [tex]$|0rangle$[/tex] and 50 percent probability of [tex]$|1rangle$[/tex]. But suppose, that instead of performing this measurement, we apply another Hadamard. This will result in the state [tex]$|0rangle$[/tex] and measurement will now result in this state with certainty. So this is kind of strange. Suppose that you wanted to replace the above description of the above quantum evolution by a single classical bit which evolves stochastically. So you are looking for an operation which when applied to a bit in the state 0 turns this state into a 50/50 mixture of the states 0 and 1. But applying this operation twice results back in the state 0. You can quickly convince yourself that there is no 2 by 2 stochastic matrix with this property. We cannot replace a single qubit by a single bit if we are to assume that each quantum gate is mapped to a stochastic map on a bit. Of course, what we are seeing here is interference: in the quantum case, the two paths that the qubit takes, one throught [tex]$|0rangle$[/tex] and the other through [tex]$|1rangle$[/tex] interfere in such a way that we end up back in the [tex]$|0rangle$[/tex] state. Since probabilities are always positive, we cannot achieve a similar evolution using stocahstic evolutions on a single bit.
But wait! What if we wanted to model this qubit experiment by a classical experiment in which we replace the qubit by two classical bits. Now what can we do? Here is an idea. We need some randomness. So lets make one of the two classical bits a bit which is a 50/50 mixture of the two states 0 and 1. Now suppose that we use the second bit to represent the state we are measuring. I.e. in the above experiment when we start in the [tex]$|0rangle$[/tex] quantum state, this means starting in the second classical bit in the state 0. Now replace the Hadamard operation in the classical case with a classical operation which swaps the two bits. Certainly if we apply this classical gate once, and measure the second bit we end up in a 50/50 mixture and if we apply the swap twice, since swaping twice is identy, if we measure the second bit it will now be back to 0! So we’ve mimiced the above quantum interference experiment using two classical bits.
Well, coming from the quantum world, you might wonder ah but what about the following experiment. Suppose that you again start your quantum world in the state [tex]$|0rangle$[/tex], apply a Hadamard and then apply a Pauli [tex]$Z=left[begin{array}{cc} 1 & 0 \ 0 & -1 end{array} right]$[/tex] gate. Now, of course, if you make a measurement you again end up in a 50/50 mixture of the states [tex]$|0rangle$[/tex] and [tex]$|1rangle$[/tex]. However, if you forgoe this measurement and apply instead now a Hadmard, you will end up in the state [tex]$|1rangle$[/tex]. So by applying a gate [tex]$Z$[/tex] which does nothing to the probabilities had you measured the system, you’ve changed the state to [tex]$|1rangle[/tex] after the Hadmard. Very strange, but we know that this is nothing more than the effect of changing the phase of one of the states such that what was previously constructive interference becomes destructive interference (and vice versa). The obvious question is whether we can now mimic this using our two classical bits. Of course! We do this by, when we apply the [tex]$Z$[/tex] quantum gate, applying a bit flip to the first bit. Thus in the above experiment we replace Hadamard [tex]$Z$[/tex] Hadamard by swap, bit flip on the first bit, swap. This will, if we start the second bit in 0 produce the final result of 1, as desired, and if we were to measure the system after the first swap or first swap and bit flip on the first bit, a 50/50 mixture as desired.
Can this be extended even further? Yep. First notice that if we look at the group of reversible operations on 2 classical bits, this is nothing more than the permutation group of four objects (the states 00, 01, 10, and 11.) There are 24 elements to this group. Now the Pauli group on a single qubit, if you forget about a global phase, which for a single qubit can have no observable effect, has only four different elements (note that moding out this phase does not produce a group since [tex]$XZ=-ZX$[/tex], so what I’m describing is a set of elements which act in an observable fashion.) The Clifford group elements which are not Pauli group elements themselves acts as the automorphism group on the Pauli group. Indeed it acts, modulo again a global phase, to permute the three nontrivial elements of Pauli group. Thus it is, modulo again a global phase, nothing more than 3!=6 permutations. The total size of the Clifford group, when we mod out the effect of a global phase is 4 times 6 or 24. But that is the size of the permutation group of four objects. Indeed you can work out that because of this, you can mimic exactly the Clifford group gates using the two bit construction detailed above. Kind of cool, no?
So what we’ve got here is a classical model of the Clifford group gates, a set of gates which exhibit interference, but where we have replaced our qubit by two bits. This second replacement doesn’t look much like a classical wave, or at least not one I’m used to. Which is what I was looking for. So interference can be understood classically here. It is nothing more than the fact that we do not measure the full state of the classical system, which can lead to effects which look effectively like constructive and destructive interference. Since we don’t have complete information about the system by just knowing the state of the second bit, we can observe a classic example of quantum interference.
[Those of you who are experts may immediately notice Spekken’s toy model and the Gottesman-Knill theorem. But if you’re an expert why are you reading my silly meandering writings? Get back to work…Carlos!]

QIPC Workshop Extended Registration

In a few weeks I’ll be heading over the pond to London to participate in the QIPC Workshop in London. Scott Aaronson and I will be kicking off the workshop with a talk entitled “What have I learned from physicists/ computer scientists and what else would I like to learn from them?” My goal will be to convince Scott that he may have learned something from physicists 🙂 Ha, right! Anyway, the registration deadline for the workshop has been extended. So register now!

Extended registration: Today is the last day for payment. We extend the registration till next Wednesday 4th October at 2pm. Please register on the web site in order to reserve your place for dinner. We need to know in advance how many dinners to order. You can pay the registration fee in cash on site during the first day of the workshop.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~The FET QIPC proactive initiative together with the ERA Pilot QIST project and the following Committee: Artur Ekert (Chairman), Harry Buhrman, Philippe Grangier, Martin Plenio, Miklos Santha, Peter Zoller, Ian Walmsley, Goran Wendin are organizing
The 7th European QIPC Workshop on Quantum Information Processing and Communication
Physicists and Computer Scientists Unite!
October 13-14, 2006 The Royal Society London, UK
Registration is obligatory and can be done on the web site: http://www.qist-europe.net/QIPC-Workshop/
We have already 122 registered participants.
Please tell your colleagues about this event. You can still decide to join us!
We are looking forward to seeing you in London!

Freezing Anomalous Heating

One problem with ion traps qubits has been the heating of the motional degrees of the trapped ions, due mostly to fluctuating potentials on the trap electrodes. The electrode potential goes yee-yaw and the ion goes wee-wah, heating up and thus ruining the motional degree of freedom of the ion. One idea has been that these potentials are thermally activated. If this is true, then cooling down the electrodes should reduce this “anomalous” heating. And indeed, here is a Physical Review Letter describing just such a result from the group at the University of Michigan using a cool double-needle radio frequency trap (See also here.) By lowering the electrodes from 300 K to approximately 150 K the group was able to reduce the heating rate by an order of magnitude. Mmmm, delicious order of magnitude.

Moxie

Ian Durham has moved his blog to Quantum Moxie. The reason:

Well, for those of you (all two of you) who read The New American Whig, my former blog, I have decided to reduce the politics and ramp up the quantum mechanics and physics in general (which is my everyday passion). Politics just gets depressing after awhile whereas physics is almost always exciting! Though my students would perhaps disagree…

Indeed, I myself have cut out politics from what I blog about for similar reasons. Also because it makes me rant even worse than I normally rant. Maybe what we need to do is to combine quantum physics with politics. I mean politicians take “positions” what’s to keep them from taking “superpositions?”

IQING 5, April 11-14, 2007 in Innsbruck, Austria

Michael Bremner (aka quantumbiodiscs), writing on behalf of the organizing committee, informs me about IQING 5 to be held in Innsbruck in April:

IQING 5 (first announcement):
IQING 5 (Informal Quantum INformation Gathering), will be held on
April 11 – 14 2007 in Innsbruck, Austria.
Like the previous incarnations of the IQING, IQING 5 is a workshop is intended for junior postdocs and research students working on either theoretical or experimental quantum information science. IQING 5 will
provide an informal environment where junior researchers can promote their work to their peers and discuss new directions in the field of quantum information science.
The organizing committee intends to have details for registration and submission available in October/November with the 1st of January as the deadline. For more information, please bookmark: http://www.iqoqi.at/events/conferences/iqing2007/

Alas it appears that I’m too old to attend! But luckily I get to visit Innsbruck in a few weeks.

Drink Orange Juice, Attend a Conference, Thaw Out

Pawel Wocjan (who just started on the faculty at the University of Central Florida, congrats!) emails me about a workshop he is helping organize. Florida in November sounds pretty warm!

Call for participation: I2Lab Workshop ‘Frontiers in Quantum and Biological Information Processing’ in Orlando, November 16-17, 2006 http://i2lab.ucf.edu/News/Workshops.html
The Workshop ‘Frontiers in Quantum and Biological Information Processing’ will be held at the University of Central Florida (UCF), in Orlando, FL, on November 16th and 17th, 2006. It is sponsored by the Interdisciplinary Information Science and Technology Laboratory (I2Lab) at UCF. The organizers are James Hickman, Michael Leuenberger, Dan Marinescu, Eduardo Mucciolo, and Pawel Wocjan.
For more information on the motivation, the program, the list of invited speakers and program directors from funding agencies, and registration go to http://i2lab.ucf.edu/News/Workshops.html
There is a limited number of slots for non-invited participants. The registration will remain open until all the slots are filled.

As an aside, anyone who is organizing a conference in quantum information science and would like an announcement like this posted on the Quantum Pontiff should feel free to send me an email. Of course a great resource is Daniel Lidar’s Quantum Computation and Information Conferences.

Young, Smart, and Ready to Quantum Compute

I just finished reading Lee Smolin’s The Trouble with Physics. No, I’m not going to review it. What do you think I want the Quantum Pontiff to turn into a gigantic ball of flaming flamable flame wars? (The publisher actually was supposed to send me a copy and may still, but with my moving it may have missed me. But not to worry I went out and bought a copy myself because I couldn’t resist.)
Actually okay here is a two second review. The book is a fast, interesting read and I recommend it to anyone who is curious as to what all the fuss on certain websites is about without having to wade through a vast collection of comment tirades. Contrary to what you might expect, loop quantum gravity is not trumpted up as an alternative to string theory in the book, instead Smolin focuses on what he sees are the challenges string theory faces and then also about how he thinks the sociology of academia causes problems at a time when revolutionary new ideas are needed (which is what Smolin argues is required to get beyond our current status in the search for a quantum theory of gravity.) This later part of the book is interesting irrespective of your views or understanding of string theory and Smolin makes the case that the academic system has a lot of weaknesses when it comes time for truely new physics.
But okay, enought about the contents of the book that I’m not qualified to comment on. Lee Smolin actually mentions quantum computing multiple times in the book. Now first I have to take him to task because I am a nitpicking little son-of-a, and I just can’t help myself. Smolin writes

In 1994, Peter Shor of MIT, who was then a computer scientist at Bell Laboratories, found a remarkable result, which is that a large enough quantum computer would be able to break any code in existence.

Whoops. No, Shor’s algorithm can break the main public key cryptosystems those based on the difficulty of factoring and the discrete logriathm, but there are still public key cryptosystems which are so far resistent to both quantum and classical attacks (like those based on certain shortest vector in a lattice problems.) So quantum computers can’t break any code in existence. But, all is well, because in the next few sentences Smolin pays quantum computer some amazing props:

..Since then money has flooded into the field of quantum computation, as governments do not want to be the last to have their codes borken. This money has supported a new generation of young, very smart scientsits- physicists, computer scientists, and mathematicians. They have created a new field, a blending of physics and computer science, a significant part of which involves a reexcamination of the foundations of quantum mechanics. All of a sudden, quantum computer is hot, with lots of new ideas and results. Some of these results address the concerns about the foundations and many could have been discovered anytime since the 1930s. Here is a clear example of how the suppresion of a field by academic politics can hold up progress for decades

See he called quantum computer people “young” and “very smart!” That’s like being called “cool” in physics language! Now if only quantum computing could follow string theory’s example and populate physics departments across the country. Perhaps those in control of U.S. physics deparments who have hired a number of quantum computing theorists countable on fingers over the last few years have secretely been doing us all a big favor by keeping us from becoming overhyped and overpopulated. Or at least overpopulated.

Canadian Quantum

Quantum Works.

QuantumWorks is a new, NSERC-funded Innovation Platform that links Canadian researchers with industrial and government agency partners to lead Canada into the next technological revolution – that of Quantum Information. Building on established national expertise in quantum cryptography, quantum algorithms and quantum information processing devices, QuantumWorks research programs will provide “made in Canada” breakthroughs, protect them, and promote them to private and public sectors. Through a national training strategy in quantum information, QuantumWorks will ensure that research labs and the work force of tomorrow are populated with quantum-aware graduates. As the Information Age gives way to the Quantum Age, QuantumWorks will ensure that Canada leads the way.

Quantum Age? Don’t they know time is not a hermitian operator in quantum theory? (Okay, David Pegg did define a POVM operator called “age” which is sort of like a conjugate variable to the energy, BTW!)
The Canadians are coming! The Canadians are coming!
(You cannot begin to understand how hard it was to resit putting the word “eh” somewhere in this post 🙂 )