Combinatorics and more

Amazing! Keith Frankston, Jeff Kahn, Bhargav Narayanan, Jinyoung Park: Thresholds versus fractional expectation-thresholds

Posted on October 30, 2019 by Gil Kalai

This post describes a totally unexpected breakthrough about expectation and thresholds. The result by Frankston, Kahn, Narayanan, and Park has many startling applications and it builds on the recent breakthrough work of Alweiss, Lovett, Wu and Zhang on the sunflower conjecture. Warm congratulations to Keith, Jeff, Bhargav, and Jinyoung!

Let me mention that important updates on the matter of applying the intermediate value theorem for football (or soccer as referred to in the US) that was discussed in this 2009 post were added to the post. For readers interested in the Google’s quantum supremacy news, here is a link of my main post on the matter.

Thresholds versus fractional expectation-thresholds

This morning the following paper appeared on the arXive: Thresholds versus fractional expectation-thresholds by Keith Frankston, Jeff Kahn, Bhargav Narayanan, and Jinyoung Park.

Abstract: Proving a conjecture of Talagrand, a fractional version of the ‘expectation-threshold’ conjecture of Kalai and the second author, we show for any increasing family F on a finite set X that $p_c(F)=O(q_f(F) \log \ell ({\bf F}))$ , where $p_c({\bf F})$ and $q_f({\bf F})$ are the threshold and ‘fractional expectation-threshold’ of F, and ℓ(F) is the largest size of a minimal member of F. This easily implies various heretofore difficult results in probabilistic combinatorics, e.g. thresholds for perfect hypergraph matchings (Johansson-Kahn-Vu) and bounded-degree spanning trees (Montgomery). We also resolve (and vastly extend) one version of the ‘random multi-dimensional assignment’ problem of Frieze and Sorkin. Our approach builds on recent breakthrough work of Alweiss, Lovett, Wu and Zhang on the Erdős-Rado ‘sunflower’ conjecture.

The expectation-threshold conjecture

The 2006 expectation threshold conjecture gives a justification for a naive way to estimate the threshold probability of a random graph property. Suppose that you are asked about the critical probability for a random graph in G(n,p) for having a perfect matching (or a Hamiltonian cycle). You compute the expected number of perfect matchings and realize that when p is C/n this expected number equals 1/2. (For Hamiltonian cycles it will be C’/n.) Of course, if the expectation is one half the probability for a perfect matching can be very low, indeed in this case, an isolated vertex is quite likely but when there is no isolated vertices the expected number of perfect matchings is rather large. Our 2006 conjecture boldly asserts that the gap between the value given by such a naive computation and the true threshold value is at most logarithmic in the number of vertices. Jeff and I tried hard to find a counterexample but instead we managed to find more general and stronger forms of the conjecture that we could not disprove.

Conjectures by Talagrand

The expectation threshold conjecture had some connections with a 1995 paper of Michel Talagrand entitled Are all sets of positive measure essentially convex? In a 2010 STOC paper Are Many Small Sets Explicitly Small? Michel formulated a weaker fractional version of the expectation threshold conjecture which is sufficient for the various applications of the original conjecture. This conjecture (as well as a stronger form also posed by Talagrand) is now verified in the new paper!

Connection to isoperimetry

In our 2006 paper we tried to relate the expectation threshold conjecture to various questions of independent interest related to stability theorems for discrete isoperimetric inequalities. This direction did not play a role in the new paper. Let me note that the isoperimetric problems served as partial motivation for the recent breakthrough results by Peter Keevash, Noam Lifshitz, Eoin Long, and Dor Minzer that are reported in this October 2018 post. See their paper Hypercontractivity for global functions and sharp thresholds.

A sample from the applications

The threshold value for perfect matching – this was proved already by Erdos and Renyi (1960) and it follow from the new results. The same goes for the threshold for connectivity.
The threshold value for Hamiltonian circuits – posed as a problem by Erdos and Renyi it was solved by Korshunov (1976) and by Posa (1976).
The threshold for perfect matching in 3-uniform hypergraphs – was posed by Schmidt and Shamir (1983) and was settled by Johansson, Kahn, and Vu. (It was one of the motivation for my 2006 paper with Jeff.)
The threshold for bounded degree spanning trees that was open for a long time and was settled by Montgomery (2019).

Let me mention that in various cases the gap between the (fractional) expectation threshold and threshold is a smaller power of log n, or is a constant, or has different behavior. Understanding this through a general theory is still unknown.

Connection to the sunflower breakthrough

What did play a major role in the new development was the recent breakthrough work of Alweiss, Lovett, Wu and Zhang on the Erdős-Rado ‘sunflower’ conjecture. (See this post.) I expected that the method of the sunflower paper will have major applications but this application took me by a surprise.

Posted in Combinatorics, Probability | Tagged Bhargav Narayanan, Jeff Kahn, Jinyoung Park, Keith Frankston | Leave a comment

Starting today: Kazhdan Sunday seminar: “Computation, quantumness, symplectic geometry, and information”

Posted on October 27, 2019 by Gil Kalai

Sunday, 27 October, 2019 – 14:00 to 16:00

Repeats every week every Sunday until Sat Feb 01 2020

Location: Ross 70

The Google supremacy claims are discussed (with updates from time to time) in this earlier post. Don’t miss our previous post on combinatorics.

Tentative syllabus for “Computation, quantumness, symplectic geometry, and information”

1. Mathematical models of classical and quantum mechanics.

2. Correspondence principle and quantization.

3. Classical and quantum computation: gates, circuits, algorithms (Shor, Grover). Solovay-Kitaev. Some ideas of cryptography

4. Quantum noise and measurement, and rigidity of the Poisson bracket.

5. Noisy classical and quantum computing and error correction, threshold theorem- quantum fault tolerance (small noise is good for quantum computation). Kitaev’s surface code.

6. Quantum speed limit/time-energy uncertainty vs symplectic displacement energy.

7. Time-energy uncertainty and quantum computation (Dorit or her student?)

8. Berezin transform, Markov chains, spectral gap, noise.

9. Adiabatic computation, quantum PCP (probabilistically checkable proofs) conjecture [? under discussion]

10. Noise stability and noise sensitivity of Boolean functions, noisy boson sampling

11. Connection to quantum field theory (Guy?).

Literature: Aharonov, D. Quantum computation, In “Annual Reviews of Computational Physics” VI, 1999 (pp. 259-346). https://arxiv.org/abs/quant-ph/9812037

Kalai, G., Three puzzles on mathematics computations, and games, Proc. Int Congress Math 2018, Rio de Janeiro, Vol. 1 pp. 551–606. https://arxiv.org/abs/1801.02602

Nielsen, M.A., and Chuang, I.L., Quantum computation and quantum information. Cambridge University Press, Cambridge, 2000.

Polterovich, L., Symplectic rigidity and quantum mechanics, European Congress of Mathematics, 155–179, Eur. Math. Soc., Zürich, 2018. https://sites.google.com/site/polterov/miscellaneoustexts/symplectic-rig…

Polterovich L., and Rosen D., Function theory on symplectic manifolds. American Mathematical Society; 2014. [Chapters 1,9] https://sites.google.com/site/polterov/miscellaneoustexts/function-theor…

Wigderson, A., Mathematics and computation, Princeton Univ. Press, 2019. https://www.math.ias.edu/files/mathandcomp.pdf

Posted in Combinatorics, Computer Science and Optimization, Geometry, Physics, Teaching | Tagged Quantization, Quantum computation, Quantum information, Symplectic geometry | Leave a comment

The story of Poincaré and his friend the baker

Posted on October 13, 2019 by Gil Kalai

Update: After the embargo update (Oct 25): Now that I have some answers from the people involved let me make a quick update: 1) I still find the paper unconvincing, specifically, the few verifiable experiments (namely experiments that can be verified classically) cannot serve as a basis for the larger experiments that cannot be classically verified. 2) Many of my attempts to poke hole in the experiments and methodology are also incorrect. 3) In particular, my suggestion regarding the calibration That I express with much confidence at the beginning of the post goes against the basic strategy of the researchers (as they now clarified) and the detailed description in the supplement. 4) I will come back to the matter in a few weeks. Meanwhile, I hope that some additional information will become available. Over the comment section you can find a proposal for a “blind” test that both Peter Shor and I agree to. (If and when needed.) It would respond to concerns about “cross-talk” between the classical computations and quantum computation during the experiments, either via the calibration method or by other means.

Original post (edited):

Here is a little update on the Google supremacy claims that we discussed in this earlier post. Don’t miss our previous post on combinatorics.

Recall that a quantum supremacy demonstration would be an experiment where a quantum computer can compute in 100 seconds something that requires a classical computer 10 hours. (Say.)

In the original version I claimed that: “The Google experiment actually showed that a quantum computer running for 100 seconds PLUS a classic computer that runs 1000 hours can compute something that requires a classic computer 10 hours. (So, of course, this has no computational value, the Google experiment is a sort of a stone soup.)” and that: “The crucial mistake in the supremacy claims is that the researchers’ illusion of a calibration method toward a better quality of the quantum computer was in reality a tuning of the device toward a specific statistical goal for a specific circuit.” However, it turned out that this critique of the calibration method is unfounded. (I quote it since we discussed it in the comment section.) I remarked that “the mathematics of this (alleged) mistake seems rather interesting and I plan to come back to it (see at the end of the post for a brief tentative account), Google’s calibration method is an interesting piece of experimental physics, and expressed the hope that in spite of what appears (to me then) to be a major setback, Google will maintain and enhance its investments in quantum information research. Since we are still at a basic-science stage where we can expect the unexpected.”)

Detection statistical flaws using statistics

Now, how can we statistically test such a flaw in a statistical experiment? This is also an interesting question and it reminded me of the following legend (See also here (source of pictures below), here, and here) about Poincaré and the baker, which is often told in the context of using statistics for detection. I first heard it from Maya Bar-Hillel in the late 90s. Since this story never really happened I tell it here a little differently. Famously, Poincaré did testify as an expert in a famous trial and his testimony was on matters related to statistics.

The story of Poincaré and his friend the baker

“My friend the baker,” said Poincaré, “I weighed every loaf of bread that I bought from you in the last year and the distribution is Gaussian with mean 950 grams. How can you claim that your average loaf is 1 kilogram?”

“You are so weird, dear Henri,” the baker replied, “but I will take what you say into consideration.”*

A year later the two pals meet again

“How are you doing dear Henri” asked the baker “are my bread loaves heavy enough for you?”

“Yes, for me they are,” answered Poincaré “but when I weighed all the loaves last year I discovered that your mean value is still 950 grams.”

“How is this possible?” asked the baker

“I weighed your loaves all year long and I discovered that the weights represent a Gaussian distribution with mean 950 grams truncated at 1 kilogram. You make the same bread loaves as before but you keep the heavier ones for me!”

“Ha ha ha” said the baker “touché!”** and the baker continued “I also have something that will surprise you, Henri. I think there is a gap in your proof that 3-manifolds with homology of a sphere is a sphere. So if you don’t tell the bread police I won’t tell the wrong mathematical proofs police :)” joked the baker.

The rest of the story is history, the baker continued to bake bread loaves with an average weight of 950 grams and Poincaré constructed his famous Dodecahedral sphere and formulated the Poincaré conjecture. The friendship of Poincaré and the baker continued for the rest of their lives.

* “There are many bakeries in Paris” thought the baker “and every buyer can weight the quality, weight, cost, and convenience”.

** While the conversation was originally in French, here, the French word touché is used in its English meaning.

The mathematics of such a hypothetical calibration in a few sentences.

The ideal distribution $D_C$ for a (freezed) random circuit can be seen exponentially distributed probabilities depending on $C$ .

The first order effect of the noise is to replace $D_C$ by a convex combination $tD_C+(1-t)J$ with a uniform distribution $J$ . (For low fidelity $t$ is rather small.)

The second order effect of the noise is adding a Gaussian fluctuation described by Gaussian-distributed probabilities $G_C$ . Like $D_C,$ these probabilities also depend on the circuit $C$ .

For low fidelity, as in our case, the calibration mainly works in the range where $G_C$ is dominant and the calibration (slightly) “cancels” this Gaussian fluctuation. This does not calibrate the quantum computer but rather tweaks it toward the specific Gaussian contribution that depends on the circuit $C$ .

Trivia question: what is the famous story where a mathematician is described as objecting to children dreaming.

Posted in Combinatorics, Computer Science and Optimization, Probability, Quantum, Statistics | Tagged Google, Henri Poincaré, quantum supremacy | 24 Comments

Gérard Cornuéjols’s baker’s eighteen 5000 dollars conjectures

Posted on October 13, 2019 by Gil Kalai

Gérard Cornuéjols

Gérard Cornuéjols‘s beautiful (and freely available) book from 2000 Optimization: Packing and Covering is about an important area of combinatorics which is lovely described in the preface to the book

The integer programming models known as set packing and set covering have a wide range of applications, such as pattern recognition, plant location and airline crew scheduling. Sometimes, due to the special structure of the constraint matrix, the natural linear programming relaxation yields an optimal solution that is integer, thus solving the problem. Sometimes, both the linear programming relaxation and its dual have integer optimal solutions. Under which conditions do such integrality properties hold? This question is of both theoretical and practical interest. Min-max theorems, polyhedral combinatorics and graph theory all come together in this rich area of discrete mathematics. In addition to min-max and polyhedral results, some of the deepest results in this area come in two flavors: “excluded minor” results and “decomposition” results. In these notes, we present several of these beautiful results. Three chapters cover min-max and polyhedral results. The next four cover excluded minor results. In the last three, we present decomposition results.

The last sentence of the preface gives this post some urgency

In particular, we state 18 conjectures. For each of these conjectures, we offer $5000 as an incentive for the first correct solution or refutation before December 2020.

The book starts with Konig’s theorem, the first figure is the Petersen graph, and among the other mathematical heroes mentioned in the book are Edmonds, Johnson, Seymour, Lovász, Lehman, Camion, Tutte, and Truemper.

The title of this post refers to Baker’s dozen. In the 13th century Bakers who were found to have shortchanged customers could be liable to severe punishment, and to guard against the punishment of losing a hand to an axe, a baker would give 13 for the price of 12, to be certain of not being known as a cheat. (Wikipedia) In this post we mention a 19th problem for which Gerard offered 5000 dollars. (I am not sure if there is time limit for that problem. I am thankful to Maria Chudnovsky for telling me about the problem.)

What happened to the 18 problems in the list?

Perhaps the most difficult problem on the list was solved first: two of the problems in the list were about perfect graphs and were settled with the solution of the strong perfect graph conjecture by Chudnovsky, Robertson, Seymour, and Thomas. Three of the problems were about balanced bipartite graphs. They were solved by Chudnovsky and Seymour in 2006. Conjecture 4.14 in Chapter 4 was solved by Jonathan Wang (2010) 30,000 dollars were thus collected and 60,000 dollars are still offered (until Dec 2020).

Balanced bipartite graphs and the 19th problem.

Balanced bipartite graphs are sort of bipartite analogs of perfect graphs. They are bipartite graphs so that every induced cycle have length divisible by four. Gerard’s 19the prize money problem is also about balanced bipartite graphs.

Conjecture: Let G be balanced. Then there is $e \in E(G)$ such that $G\backslash e$ is a balanced graph.

In other words every balanced bipartite graph contains an edge which is not a unique chord in any cycle.

This conjecture is Conjecture 5.20 in

M. Conforti, G. Cornuejos, K. Vuskovic Balanced matrices

In that paper, this conjecture is attributed to:

M. Conforti and M.R Rao “Structural properties and decomposition of linear
balaced matrices”, Mathematical Programming 55 (1992) 129-168.

Posted in Combinatorics, Computer Science and Optimization, Open problems | Tagged Gérard Cornuéjols, Maria Chudnovsky, Neil Robertson, Paul Seymour, Robin Thomas | 3 Comments

Noisy quantum circuits: how do we know that we have robust experimental outcomes at all? (And do we care?)

Posted on October 3, 2019 by Gil Kalai

In a recent post we discussed Google’s claim of achieving “quantum supremacy” and my reasons to think that these claims will not stand. (See also this comment for necessary requirements from a quantum supremacy experiment.) This debate gives a good opportunity to discuss some conceptual issues regarding sampling, probability distributions, statistics, and computational complexity. This time we will discuss chaotic behavior vs. robust experimental outcomes.

On unrelated matter, I just heard Shachar Lovett’s very beautiful TCS+ lecture on the sunflower conjecture (see this post on the Alweiss, Lovett, Wu, and Zhang’s breakthrough). You can see the lecture and many others on the TCS+ you tube channel.

Slide 30 from my August, ’19 CERN lecture: predictions of near-term experiments. (Here is the full powerpoint presentation.) In this post we mainly discuss point b) about chaotic behavior. See also my paper: The argument against quantum computers.

Consider an experiment aimed for establishing quantum supremacy: your quantum computer produced a sample $x_i$ which is a 0-1 string of length $n$ from a certain distribution $D_i$ . The research assumption is that $D_i$ is close enough to a fixed distribution $D$ ( $D$ accounts for the computing process and the noise) which is very hard to be demonstrated on a classical computer. By looking at a large number of samples you can perform a statistical test on the samples to verify that they were (approximately) sampled from $D$ , or at least that they were sampled from a probability distribution that is very hard to be computed on a classical computer!

But, is it possible that all the distributions $D_i$ ‘s are very different? Namely that each sample is taken from a completely different distribution? More formally, is it possible that under a correct modeling of the device for two different samples $x_i$ and $x_j$ , $D_i$ has a very small correlation with $D_j$ ? In this case we say that the experiment outcomes are not robust and that the situation is chaotic.

Here are a couple of questions that I propose to think about:

How do we test robustness?
Do the supremacy experiments require that the experiment is robust?
If, after many samples, you reach a probability distribution that require exponential time on a classical computer should you worry about the question whether the experiment is robust?
Do the 10,000,000 samples for the Google 53-qubit experiment represent a robust sampling experiment?

Posted in Computer Science and Optimization, Quantum | Tagged chaos, chaos and computation, quantum supremacy | 9 Comments

Test Your Intuition 40: What Are We Celebrating on Sept, 28, 2019? (And answer to TYI39.)

Posted on September 28, 2019 by Gil Kalai

Update: We are celebrating 10 years anniversary to Mathoverflow

Domotorp got the answer right. congratulations, Domotorp!

To all our readers:
Shana Tova Umetuka – שנה טובה ומתוקה – Happy and sweet (Jewish) new year.

Continue reading →

Posted in Test your intuition, What is Mathematics | Tagged Mathoverflow, Test your intuition | 6 Comments

Quantum computers: amazing progress (Google & IBM), and extraordinary but probably false supremacy claims (Google).

Posted on September 23, 2019 by Gil Kalai

A 2017 cartoon from this post.

After the embargo update (Oct 25): Now that I have some answers from the people involved let me make a quick update: 1) I still find the paper unconvincing, specifically, the verifiable experiments (namely experiments that can be tested on a classical computers) cannot serve as a basis for the unverifiable fantastic claims. 2) Many of my attempts to poke hole in the experiments and methodology are also incorrect. 3) In particular, my suggestion regarding the calibration goes against the description in the supplement and the basic strategy of the researchers. 4) I will come back to the matter in a few weeks. Meanwhile, I hope that some additional information will become available. Post rearranged chronologically.

Some main issues described in the post and also this critique was brought to the attention of John Martinis and some of the main researchers of the experiment on October 9, 2019.

(Oct 28, 2019) The paper refers to an external site with all the experimental results. Here is the link https://datadryad.org/stash/dataset/doi:10.5061/dryad.k6t1rj8. In my view, it will be valuable, (especially, for an experiment of this magnitude) if there will be an independent verification of the statistical computations.

(October 23, 2019). The paper (with a supplementary long paper) is now published in Nature. The published versions look similar to the leaked versions.

Original post: For my fellow combinatorialists here is the link to the previous post on Kahn-Park’s result, isoperimetry, Talagrand, nice figures and links. Quick update (Sept. 27) Avi Wigderson’s book is out!

Recent quantum computer news

You already heard by now that Google (informally) announced it achieved the milestone of “quantum supremacy” on a 53 qubit quantum computer. IBM announced launching in October a quantum computer also on 53 of qubits. Google’s claim of quantum supremacy is given in two papers from August that were accidentally leaked to the public. Here are links to the short main paper and to the long supplementary paper. The paper correctly characterizes achieving quantum supremacy as an achievement of the highest caliber.

Putting 50+ qubits together and allowing good quality quantum gates to operate on them is a big deal. So, in my view, Google and IBM’s noisy quantum circuits represent a remarkable achievement. Of course, the big question is if they can do some interesting computation reliably, but bringing us to the place that this can be tested at all is, in my view, a big deal!

Of course, demonstrating quantum supremacy is even a much bigger deal, but I expect that Google’s claim will not stand. As you know, I expect that quantum supremacy cannot be achieved at all. (See this post, this paper A, this paper B, and these slides of my recent lecture at CERN.) My specific concerns expressed in this post are, of course, related to my overall skeptic stance as well as to some technical points that I made in my papers, but they could (and should) have also been made by responsible quantum computer believers.

Achieving quantum supremacy via sampling

In the last decade there were several suggestions to demonstrate the computational superior power of quantum circuits via sampling tasks. The computer creates (approximately) a probability distribution D on 0-1 strings of length n (or other combinatorial objects) that we have good computational complexity reasons to think that classical computers cannot achieve. In our case, D is the probability distribution obtained by measuring the outcome of a fixed pseudo-random quantum circuit.

By creating a 0-1 distribution we mean sampling sufficiently many times from that distribution D so it allows us to show that the sampled distribution is close enough to D. Because of the imperfection (noise) of qubits and gates (and perhaps some additional sources of noise) we actually do not sample from D but from another distribution D’. However if D’ is close enough to D, the conclusion that classical computers cannot efficiently sample according to D’ is plausible.

How to run supremacy sampling experiment

You compare the distribution E obtained by the experiment to the ideal distribution D for increasingly larger values of n. If there is a good match this supports your supremacy claims.

There are two important caveats:

A single run of the quantum computer gives you only one sample from D’ so to get a meaningful description of the target distribution you need to have many samples.
Computing the ideal distribution D is computationally hard so as n increases you need a bigger and bigger computational effort to compute D.

Still, if you can show that D’ is close enough to D before you reach the supremacy regime, and you can carry out the sampling in the supremacy regime then this gives you good reason to think that your experiments in the supremacy regime demonstrate “quantum supremacy”.

Earlier experiments

The Google group itself ran this experiment for 9 qubits in 2017. One concern I have with this experiment is that I did not see quantitative data indicating how close D’ is to D. Those are distributions on 512 strings that can be described very accurately. (There were also some boson sampling experiments with 6 bosons and 2 modes and 5 bosons with 5 modes. In this case, supremacy requires something like 50 bosons with 100 modes.)

The twist in Google’s approach

The twist in Google’s approach is that they try to compute D’ based mainly on the 1-qubit and 2-qubit (and readout errors) errors and then run an experiment on 53 qubits where they can neither compute D nor verify that they sample from D’. In fact they sample $10^7$ samples from 0-1 strings of length 53 so this is probably much too sparse to distinguish between D and the uniform distribution even if we have unlimited computational power. (Actually as several people mentioned the last sentence is incorrect.)

The missing part in the experiment.

The obvious missing part in the experiment is to run the experiment on random circuits with 9-25 qubits and to test the research assumption about D’. I find it a bit surprising that apparently this was not carried out. What is needed is experiments to understand probability distributions obtained by pseudorandom circuits on 9-, 15-, 20-, 25- qubits. How close they are to the ideal distribution D and how robust they are (namely, what is the gap between experimental distributions for two samples obtained by two runs of the experiment.)

Actually, as I noted in the introduction to Paper A (subsection on near term plans for “quantum supremacy” and Figure 3), you can bring the hypothesis of quantum supremacy via pseudo-random circuits into test already in the 10-30 qubit regime without even building 53- or 72- qubit devices. (I can certainly see the importance in building larger circuits that are necessary for good quality error correcting codes.)

The main potential mistake and the matter of correlation.

(Oct 18): In hindsight this section about correlation is not relevant to the Google supremacy story.

Let me also indicate what is a potential mistake in the computation of D’ relying just on the behavior of qubits and gates. This is related to correlated (2-qubit gate) errors that I studied mainly before 2014.

The general picture regarding correlated qubit errors is the following:

(1) Errors for gated qubits (for a CNOT gate) are (substantially) positively correlated.

Here, you can think about the extreme form of “bad” noise where with a small probability t both gated qubits are corrupted and with probability (1-t) nothing happens. (“Good” noise is when each qubit is corrupted with probability t, independently. Real life 2-qubit noise is a certain mixture of good and bad noise.)

(2) Therefore, (unless you are below the threshold level and apply quantum fault tolerance scheme) qubits in cat states that were created indirectly will have correlated noise of this kind.

(3) Therefore (and going from (2) to (3) is a mathematical part) probability distributions described by pseudorandom circuits will have a strong effect of synchronized errors.

What is most devastating about correlated errors is that the accumulated error-rate in terms of qubit errors becomes quadratic in the number of rounds instead of linear. See Remark 4.2 about “model error-rate” and “effective error-rate” in Paper A.

My predictions.

Let me mention that Paper B describes fairly detailed predictions about probability distributions obtained by pseudo-random circuits and these predictions can be tested in the 9-25 qubits range. In particular, they suggest that robust outcomes will be easy to simulate classically, as they belong to a very low level (LDP) computational complexity class, and that noise sensitivity will lead to chaotic outcomes which are far from the ideal distribution.

A problem with the supremacy statements itself.

On Google Cloud servers, we estimate that performing the same task for m = 20 with 0.1% fidelity using the SFA algorithm would cost 50 trillion core-hours and consume 1 petawatt hour of energy. To put this in perspective, it took 600 seconds to sample the circuit on the quantum processor 3 million times, where sampling time is limited by control hardware communications; in fact, the net quantum processor time is only about 30 seconds.

It is not clear where these fantastic numbers come from. They refer to a specific algorithm and there might be some vague reason to think that this algorithm cannot be improved for D or near by distributions. But, for example, for the probability distribution I predict this algorithm is extremely inefficient and the sampling can be carried out efficiently.

Distance-3 surface code

In 2013 I was one of the organizers of a conference Qstart celebrating our then new Quantum Science Center. John Martinis gave a lecture where he mentioned building distance-3 surface codes on 20+ qubits as a (then) near term task. My argument against quantum computers does not give a definite prediction whether distance-3 surface codes are within or beyond reach and it would be interesting to examine it.

Conclusion

It looks that Martinis’ groups announcement of supremacy, while based on a remarkable experimental progress, was premature and in my view it is mistaken. (To be fair, the papers themselves were prematurely released.) This post was also written rather quickly so I will certainly have to think about matters further, perhaps also in view of more careful reading of the papers, some comments by members of the Google group themselves and other people, and also Scott Aaronson promised to write about it.

Links and updates

My papers and early posts

Paper A: Three puzzles on mathematics computations, and games, Proc. Int
Congress Math 2018, Rio de Janeiro, Vol. 1 pp. 551–606.

Paper B: The argument against quantum computers, To appear in: Hemmo, Meir and Shenker, Orly (eds.) Quantum, Probability, Logic: Itamar Pitowsky’s Work and Influence, Springer, Nature (2019), forthcoming

Paper C: The quantum computer puzzle, Notices AMS, May 2016

my ICM 2018 videotaped lecture (Also about other things)

My videotaped CERN 2019 lecture (I am not sure how well it works) and the slides.

A cartoon-post from 2017: If quantum computers are not possible why are classical computers possible?

The authors

Whether it stands or refuted the Google paper represents serious multidisciplinary effort, an important moment for the scientists involved in the project, and a notable event in science!

Jeff Kahn and Jinyoung Park: Maximal independent sets and a new isoperimetric inequality for the Hamming cube.

Posted on September 22, 2019 by Gil Kalai

Three isoperimetric papers by Michel Talagrand (see the end of the post)

Discrete isoperimetric relations are of great interest on their own and today I want to tell you about a new isoperimetric inequality by Jeff Kahn and Jinyoung Park which leads to a solution to an old problem on the number of maximal independent sets. (I am thankful to Nathan Keller who told me about the new papers on the arXiv and to Jeff and Jinyoung who told me about the results a few months ago.)

Unrelated news: In connection with some a forthcoming announcement by Google regarding quantum computers, Scott Aaronson commented on his blog ” Gil Kalai’s blog will indeed be an extremely interesting one to watch … you might get to witness the real-time collapse of a worldview! 😉” Thanks for the publicity, Scott! Stay tuned, folks! For my current worldview see this post.

Two papers by Jeff Kahn and Jinyoung Park

The number of maximal independent sets in the Hamming cube

Abstract: Let $Q_n$ be the n-dimensional Hamming cube and $N=2^n$ . We prove that the number of maximal independent sets in $Q_n$ is asymptotically $2n2^{N/4}$ ,
as was conjectured by Ilinca and the first author in connection with a question of Duffus, Frankl and Rödl.
The value is a natural lower bound derived from a connection between maximal independent sets and induced matchings. The proof that it is also an upper bound draws on various tools, among them “stability” results for maximal independent set counts and old and new results on isoperimetric behavior in $Q_n$ .

An isoperimetric inequality for the Hamming cube and some consequences

Abstract: (Slightly modified.)

Our basic result, an isoperimetric inequality for Hamming cube $Q_n$ , can be written:
$\int h_A^\beta d\mu \ge 2 \mu(A)(1-\mu(A))$ .
Here $\mu$ is uniform measure on $V={0,1}^n(=V(Q_n)); \beta=log_2(3/2);$ and, for $S\subset V$ and $x\in V$ , $h_S(x)$ is zero if $x \notin S$ , and $h_S(x)$ is the number of neighbors of $a$ not in $S$ , if $x \in S$ . (where $d_T(x)$ is the number of neighbors of $x$ in $T$ ).

This implies inequalities involving mixtures of edge and vertex boundaries, with related stability results, and suggests some more general possibilities. One application, a stability result for the set of edges connecting two disjoint subsets of V of size roughly |V|/2, is a key step in showing that the number of maximal independent sets in $Q_n$ is $(1+o(1))2n\exp_2[2^{n-2}]$ This asymptotic statement, whose proof will appear separately, was the original motivation for the present work.

Discussion

Counting independent sets in graphs and hypergraphs and related things.

Asymptotic enumeration of independent sets (and number of colorings) in various graph is a big topic with very remarkable techniques and methods, and there are quite a few results when the graph in question is that of the discrete $n$ -cube. The maximal size of an independent set is $2^{n-1}$ and you may recall that the recently solved (by Hao Huang) sensitivity conjecture asked for the properties of an induced subgraph on $2^{n-1}+1$ vertices.

How many independent sets are there? Well, we can consider all the subsets of the two independent sets of size $2^{n-1}$ so this gives us $2\cdot 2^{2^{n-1}}$ . Korshunov and Sapozhenko proved in 1983 that the number is $2\sqrt e$ $(1+o(1))2^{2^{n-1}}$ , and here is a link to a paper of Galvin describing a beautiful proof by Sapozhenko for this result. As an exercise you can try to figure out where the $2 \sqrt e$ term comes from.

Now, lets talk about maximal independent sets. The Kahn-Park asymptotic formula $2n2^{N/4}$ is very clean: try to figure the lower bound!

Two related results in this spirit: Erdos, Kleitman and Rothschild (1976): triangle-free graphs are almost always bipartite. The solution of Dedekind’s problem on the number of antichains of subsets of an $n$ -elemet set by Korshunov (1980) and by Sapozhenko (1991).

Talagrand’s inequality and the Kahn-Park inequality.

Let $A$ be a subset of the vertices of the discrete $n$ -cube. For every vertex $x$ in $A$ we define $h_A(x)$ as the number of neighbors of $x$ that are not in $A$ . We define $h_A(x)=0$ if $x$ does not belong to $A$ . ( $h_A(x)$ is a variation on the sensitivity function of $A$ .)

Recall that $\mu$ denote the uniform probability measure on the discrete cube. A classic discrete isoperimetric inequality that goes back (in a stronger form) to Harper and others asserts that

$\int h_A(x) d\mu \ge 2 \mu(A)(1-\mu(A))$

(The left hand side is 1/2 times the average sensitivity aka total influence of $A$ .)

Talagrand proved that $\int h_A^{1/2}(x) d\mu \ge \sqrt 2 \mu(A)(1-\mu(A))$ . This result is sharp up to some multiplicative constant both for subcubes and for Hamming balls. We discussed Talagrand’s result in this post.

Let $\beta=log_2(3/2)= .585...$ . Kahn and Park proved that

$\int h_A^{\beta}(x) d\mu \ge 2 \mu(A)(1-\mu(A))$

Note that the exponent is higher than Talagrand’s exponent. The new inequality is sharp on the nose for subcubes of codimension one and two. Let’s check it: for codimension 1, $h_A$ is constant 1 on $A$ , so $\int h_A^{\beta}(x) d\mu$ is 1/2 for every $\beta$ and this equals $2 \mu(A) (1-\mu (A))$ . When $A$ is a codimension 2 subcube, $h_A$ is constant 2 on $A$ . Now, by the definition of $\beta$, $2^\beta = 3/2$ . Thus, $\int h_A^{\beta}(x) d\mu=\frac {1}{4} \frac {3}{2}=\frac{3}{8}$ and $2 \mu(A) (1-\mu (A))=2 \frac {1}{4} \frac{3}{4}=\frac{3}{8}$ , walla!

For the relation between the Kahn-Park isoperimetric inequality and the Kahn-Park theorem on counting maximal independent sets I refer you to the original paper. The two papers are beautifully written.

Three pictures of some important isoperimetric results by Talagrand

Here are drawings and links regarding Talagrand’s three isoperimetric papers and subsequent papers, and I hope to come back to discuss them in the future. Continue reading →

Posted in Combinatorics | Tagged Jeff Kahn, Jinyoung Park, Michel Talagrand | 3 Comments

Alef’s corner: Bicycles and the Art of Planar Random Maps

Posted on September 17, 2019 by Gil Kalai

The artist behind Alef’s corner has a few mathematical designs and here are two new ones. (See Alef’s website offering over 100 T-shirt designs.)

which was used for the official T-shirt for Jean-François Le Gall’s birthday conference.

See also this quanta magazine article by Kevin Hartness.

Posted in Art, Combinatorics, Geometry, Probability | Tagged Alef's corner | Leave a comment

Paul Balister, Béla Bollobás, Robert Morris, Julian Sahasrabudhe, and Marius Tiba: Flat polynomials exist!

Posted on September 9, 2019 by Gil Kalai

Béla Bollobás and Paul Erdős at the University of Cambridge in 1990. Credit George Csicsery (from the 1993 film “N is a Number”) (source)

(I thank Gady Kozma for telling me about the result.)

An old problem from analysis with a rich history and close ties with combinatorics is now solved!

The paper is: Paul Balister, Béla Bollobás, Robert Morris, Julian Sahasrabudhe, and Marius Tiba, Flat Littelwood Polynomials exist

Abstract: We show that there exist absolute constants Δ > δ > 0 such that, for all n⩾2, there exists a polynomial P of degree n, with ±1 coefficients, such that

$\delta \sqrt n \le |P(z)| \le \Delta \sqrt n$

for all z ∈ C with |z|=1. This confirms a conjecture of Littlewood from 1966.

A little more about the result

It is still a major open problem to replace $\delta$ by $(1-o(1))$ and $\Delta$ by $1+o(1)$ (ultra-flat polynomials).

The problem can be traced back to a 1916 paper by Hardy and Littlewood.

Shapiro (1959) and Rudin (1959) showed the existence of such polynomials when you only require $P(z) \le \Delta \sqrt n$ for all z ∈ C with |z|=1.

The new result confirms a conjecture of Littlewood from 1966 and answers a question by Erdős from 1957.

If one allows complex coefficients of absolute value one, ultra flat polynomials exist by a result of Kahane (1980). Bombieri and Bourgain (2009) gave an explicit construction with sharper bounds.

The proof relies strongly on Spencer’s famous result :”Six standard deviation suffices”. (In fact, on a version of Spencer’s result by Lovett and Meka.) Continue reading →

Posted in Analysis, Combinatorics | Tagged Béla Bollobás, Flat polynomials, Julian Sahasrabudhe, Marius Tiba, Paul Balister, Robert Morris | 1 Comment

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Thresholds versus fractional expectation-thresholds

The expectation-threshold conjecture

Conjectures by Talagrand

Connection to isoperimetry

A sample from the applications

Connection to the sunflower breakthrough

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Tentative syllabus for “Computation, quantumness, symplectic geometry, and information”

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Detection statistical flaws using statistics

The story of Poincaré and his friend the baker

The mathematics of such a hypothetical calibration in a few sentences.

Trivia question: what is the famous story where a mathematician is described as objecting to children dreaming.

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What happened to the 18 problems in the list?

Balanced bipartite graphs and the 19th problem.

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Update: We are celebrating 10 years anniversary to Mathoverflow

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Recent quantum computer news

Achieving quantum supremacy via sampling

How to run supremacy sampling experiment

Earlier experiments

The twist in Google’s approach

The missing part in the experiment.

The main potential mistake and the matter of correlation.

My predictions.

A problem with the supremacy statements itself.

Distance-3 surface code

Conclusion

Links and updates

My papers and early posts

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Two papers by Jeff Kahn and Jinyoung Park

Discussion

Counting independent sets in graphs and hypergraphs and related things.

Talagrand’s inequality and the Kahn-Park inequality.

Three pictures of some important isoperimetric results by Talagrand

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A little more about the result

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