I am sure many of us are thinking about the eclipse.
It all starts with how far are we going to drive in order to see totality. My family and I are currently in Colorado, so we are relatively close to the path of darkness in Wyoming. I thought about trying to book a hotel room. But if you’d like to see the dusk in Lusk, here is what you get:
Let us just say that I became quite acquainted with small-town WY and any-ville NE before giving up. Driving in the same day for 10 hours with my two children, ages 4 and 5, was not an option. So I will have to be content with 90% coverage.
90% coverage sounds like it is good enough… But when you think about the sun and its output, you realize that it won’t actually be very dark. The sun gives out about 1kW of light and heat per square meter. 90% of that still leaves us with 100W per meter squared. Imagine a room lit by a square array of 100W incandescent bulbs at one meter apart from each other. Not so dark. Luckily, we have really dark eclipse glasses.
All things considered, it is a huge coincidence that the moon is just about the right size and distance from the earth to block the sun exactly, 
On a more personal note, another coincidence of a lesser cosmic meaning is that my wife, Jocelyn Holland, a professor of comparative literature at UCSB and Caltech, has also done research on eclipses. She has recently published an essay that shows how, for nineteenth-century observers, and astronomers in particular, the unique darkness associated with the eclipse during totality shook their subjective experience of time. Readers might want to share their own personal experiences at the end of this blog so that we can see how a twenty-first century perspective compares.
As for Jocelyn’s paper, here is a redacted ‘poetry for scientists’ excerpt from it.
Eclipses are well-known objects of scientific study but it is just as true that, throughout history, they have been perceived as the most supernatural of events, permitting superstition and fear to intrude. As a result, eclipses have frequently been used across cultures, in particular, by the community of scientists and scholars, as an index of “enlightenment.” Astronomers in the nineteenth century – an epoch that witnessed several mathematical advances in the calculation of solar and lunar eclipses, as exemplified in the work of Friedrich Bessel – looked back at prior centuries with scorn, mocking the irrational fears of times past. The German astronomer Ludwig August Busch, in text published shortly before a total eclipse in 1851, points out with some smugness that scarcely 200 years before then, in Germany, “the majority of the population threw itself upon its knees in desperation during a total eclipse,” and that the composure with which the next eclipse will be greeted is “the most certain proof how only science is able to conquer prejudices and superstition which prior centuries have gone through.”
Two solar eclipses were witnessed by Europeans in the mid-nineteenth century, on July 8th, 1842 and July 28th, 1851, when the first photographic image of an eclipse was made by Julius Berkowski (see below).
What Berkowski’s daguerreotype cannot convey, however, is a particular perception shared by both professional astronomers and amateur observers of these eclipses: that the darkness of the eclipse’s totality is unlike any darkness they had experienced before. As it turns out, this perception posed a challenge to their self-proclaimed enlightenment.
There was already a historical record in place describing the strange darkness of a total eclipse. As another nineteenth-century astronomer, Jacob Lehmann, phrased it, “How is it now to be explained, namely what several observers report during the eclipse of 1706, that the darkness at the time of the total occultation of the sun compares neither to night nor to dusk, but rather is of a particular kind. What is this particular kind?” The strange darkness of the eclipse presents a problem that one can state quite simply in temporal terms: it corresponds to no prior experience of natural light or time of day.
It might strike us as odd that August Ludwig Busch, the same astronomer who derided the superstition of prior generations, writes the following with reference to eclipses past, and in anticipation of the eclipse of 1851:
You will all remember the inexplicable melancholic frame of mind which one already experiences during large if not even total eclipses, when all objects appear in a dull, unusual light, there lies namely in the sight of great plains and far-spread drifts, upon which trees and rocks, although still illuminated by sunlight, still seem to cast no shadow, such a thing which causes mourning, that one is involuntarily overcome by horror. This feeling should occur more intensely in people when, during the total eclipse, a very peculiar darkness arrives which can be named neither night nor dusk.
August Ludwig Busch.
One can say that the perceived relationship between the quality of light and time of day is based on expectations that are so innate as to be taken as infallible until experience teaches otherwise. It is natural for us to use the available light in the sky as the basis for a measure of time when no time-keeping piece is on hand. The cyclical predictability of a steady increase and decrease in available light during the course of the day, however, in addition to all the nuances of how the midday light differs from dawn and twilight, is less than helpful in the rare event of an eclipse. The quality of light does not correspond to any experience of lived time. As a consequence, not only August Ludwig Busch, but also numerous other observers, attributed it to death, as if for lack of an alternative.
For all their claims of rationality, nineteenth-century observers were troubled by this darkness that conformed to no experienced time of day. It signaled to them, among other things, that time and light are out of joint. In short, as natural and as it may be, a full solar eclipse has, historically, posed a real challenge: not to the predictability of mechanical time-keeping, but rather to a very human experience of time.
and 
are two 
Hermitian matrices that are positive semi-definite, then their 
and 
are rank one positive semi-definite matrices, since in this case 
is also a rank one positive semi-definite matrix. The general case then follows by noting from the spectral theorem that a general positive semi-definite matrix can be expressed as a non-negative linear combination of rank one positive semi-definite matrices, and using the bilinearity of the Hadamard product and the fact that the set of positive semi-definite matrices form a convex cone. A modification of this argument also lets one replace “positive semi-definite” by “positive definite” in the statement of the Schur product theorem.
with non-negative coefficients 
is entrywise positivity preserving on the space 
of ![\displaystyle P[A] := (P(a_{ij}))_{1 \leq i,j \leq N}](https://s0.wp.com/latex.php?latex=%5Cdisplaystyle++P%5BA%5D+%3A%3D+%28P%28a_%7Bij%7D%29%29_%7B1+%5Cleq+i%2Cj+%5Cleq+N%7D&bg=ffffff&fg=000000&s=0 "\displaystyle P[A] := (P(a_{ij}))_{1 \leq i,j \leq N}")
to 
is also positive semi-definite. (As before, one should caution that ![{P[A]}](https://s0.wp.com/latex.php?latex=%7BP%5BA%5D%7D&bg=ffffff&fg=000000&s=0 "{P[A]}")
is not the application 
of ![\displaystyle P[A] = c_0 A^{\circ 0} + c_1 A^{\circ 1} + \dots + c_d A^{\circ d},](https://s0.wp.com/latex.php?latex=%5Cdisplaystyle++P%5BA%5D+%3D+c_0+A%5E%7B%5Ccirc+0%7D+%2B+c_1+A%5E%7B%5Ccirc+1%7D+%2B+%5Cdots+%2B+c_d+A%5E%7B%5Ccirc+d%7D%2C&bg=ffffff&fg=000000&s=0 "\displaystyle P[A] = c_0 A^{\circ 0} + c_1 A^{\circ 1} + \dots + c_d A^{\circ d},")
is the Hadamard product of 
copies of 
is any subset of 
and 
will be entrywise positivity preserving on the set 
of positive definite matrices with entries in ![{I = [0,\rho]}](https://s0.wp.com/latex.php?latex=%7BI+%3D+%5B0%2C%5Crho%5D%7D&bg=ffffff&fg=000000&s=0 "{I = [0,\rho]}")
, such functions are precisely the 
is a function that is entrywise positivity preserving on 
for all 
, then it must be of the form 
replaced by other domains, appear in the work of 
, a function would be entrywise positivity preserving on 
if and only if 
order must be non-negative in order for 
for some 
. In particular, if 
must be non-negative. In fact, a stronger assertion can be made, namely that the first 
, one can furthermore show that any negative term in 
, let 
be a sign. 
is preceded by at least 
with 
). Then, for any 
, with each 
having the sign of 
, which is entrywise positivity preserving on 
. 
with 
). Then there exists a convergent power series 
, with each 
.
, or the complex disk 
, but it turns out that there are far fewer entrywise positivity preserving functions in those cases basically because of the non-trivial zeroes of Schur polynomials in these ranges; see the paper for further discussion. We also have some quantitative bounds on how negative some of the coefficients can be compared to the positive coefficients, but they are a bit technical to state here.
![{\mathrm{det} P[ {\bf u} {\bf u}^* ]}](https://s0.wp.com/latex.php?latex=%7B%5Cmathrm%7Bdet%7D+P%5B+%7B%5Cbf+u%7D+%7B%5Cbf+u%7D%5E%2A+%5D%7D&bg=ffffff&fg=000000&s=0 "{\mathrm{det} P[ {\bf u} {\bf u}^* ]}")
of polynomials 
; the positivity of these determinants can be used (together with a continuity argument) to establish the positive definiteness of ![{P[uu^*]}](https://s0.wp.com/latex.php?latex=%7BP%5Buu%5E%2A%5D%7D&bg=ffffff&fg=000000&s=0 "{P[uu^*]}")
for various ranges of 
. Using the 
and the signs of the coefficients in the linear combination are determined by the signs of the coefficients of 
applied to 
, where the weight 
of the Schur polynomial is determined by 
in a simple fashion. The problem then boils down to obtaining upper and lower bounds for these Schur polynomials. Because we are restricting attention to matrices taking values in 
and another positive semi-definite matrix 
that vanishes on the last row and column (and is thus effectively a positive definite 
matrix). Using the fundamental theorem of calculus to continuously deform the rank one matrix ![{P[{\bf u} {\bf u}^*]}](https://s0.wp.com/latex.php?latex=%7BP%5B%7B%5Cbf+u%7D+%7B%5Cbf+u%7D%5E%2A%5D%7D&bg=ffffff&fg=000000&s=0 "{P[{\bf u} {\bf u}^*]}")
combined with an induction hypothesis on 
is a diagram like this:
For example, if 
and 
mapped to a set 
is equipped or, as we like to say, ‘decorated’ with extra structure. For example:
and the inputs would become outputs and vice versa. One reason for distinguishing them is that we can then attach the outputs of one circuit to the inputs of another and build a larger circuit. If we think of our circuit as a morphism from the input set 
and get a decorated cospan from 
So with luck, we get a category with objects of 
one from 
provides the map from one to the other. If 
.
between Majorana modes divided by the superconducting coherence length 
.
, vanishes exponentially while the dephasing time 
becomes exponentially long.
.
has:
of types.
where 
. Here 
are the types of the inputs, while 
is the type of the output.
and 
operations
as a little gizmo like this:
So, for example, if you operation takes two real numbers, adds them and spits out the closest integer, both input types would be ‘real’, while the output type would be ‘integer’.
we can compose it with 
like this:
for this to work! This is the whole point of types: they forbid us from composing operations in ways that don’t make sense.
of the operad 
such that the operations of 
a set 
of things of type 
that is, a collection of maps
into a function that eats things of types 
as its set of types, he calls an ‘
nodes is a famous problem: the 
And then he’s saying it’s widely believed that not gates can’t reduce the complexity to a polynomial.
of ![[n]^n](https://s0.wp.com/latex.php?latex=%5Bn%5D%5En&bg=ffffff&fg=333333&s=0 "[n]^n")
are chosen, then 
for some function 
— note that the standard deviation of the sum has order 
, so the idea is that this condition should be satisfied one way or the other with probability 
).
of random dice, the event that 
and 
be elements of 
is very small. Since typically the modulus of 
has order 
.
,
. Note also that
.
is 
, and Chernoff’s bounds imply that the probability that there exists 
with 
is, for suitable 
. Let us now fix some 
is a sum of 
. The expectation of this sum is 
. 
, 
.
the difference between 
is at most 
. Writing this out, we have
,
.
, it follows that with high probability 
, which implies that 
, then with high probability 
and 
are of order 
is somewhat like a random walk that is constrained to start and end at zero. There are results that show that random walks have a positive probability of never deviating very far from the origin — at most half a standard deviation, say — so something like the following idea for proving the first step (remaining agnostic for the time being about the precise definition of “close”). We choose some fixed positive integer 
be integers evenly spread through the interval 
. Then we argue — and this should be very straightforward — that with probability bounded away from zero, the values of 
and 
are close to each other, where here I mean that the difference is at most some small (but fixed) fraction of a standard deviation.
and 
are short, that 
and 
are uniformly close with positive probability.
and 
are almost certainly close too. Thomas Budzinski sketches an argument of the first kind, and my guess is that that is indeed needed. But either way, I think it ought to be possible to prove something like this.
independently (according to some distribution) and conditioning on some suitable event. (A quick thought here is that it would be enough if we could approximate the distribution of 
is the marginal distribution of that ![[n]](https://s0.wp.com/latex.php?latex=%5Bn%5D&bg=ffffff&fg=333333&s=0 "[n]")
and subsets of ![[2n-1]](https://s0.wp.com/latex.php?latex=%5B2n-1%5D&bg=ffffff&fg=333333&s=0 "[2n-1]")
of size 
one takes the subset 
, and given a subset ![S=\{s_1,\dots,s_n\}\subset[2n-1]](https://s0.wp.com/latex.php?latex=S%3D%5C%7Bs_1%2C%5Cdots%2Cs_n%5C%7D%5Csubset%5B2n-1%5D&bg=ffffff&fg=333333&s=0 "S=\{s_1,\dots,s_n\}\subset[2n-1]")
, where the 
are written in increasing order, one takes the multiset of all values 
, with multiplicity.) Somehow a subset of 
and conditioning on the number of elements being exactly 
, 
, 
, . 
, directed downwards, dividing the plane region 
dividing the plane region 
,, are represented as beads between the arrows and proarrows 
,
together with two 2-cells 
and 
such that
= 
= 
together with two 2-cells 
and 
such that
.
, given by the vertical cells 
and 
, satisfying the zig-zag identities
= 
= 
and 
. Bending the zig-zag identities shows that these maps are inverse to each other
= 
= 
is a natural isomorphism with inverse 
. That is,
= 
= 
and counit 
by bending. These satisfy the zig-zag identities by pulling straight and using (1):
= 
= 
= 
= 
= 
were sequences going to infinity, 
were distinct integers, and 
were 
-bounded multiplicative functions which were non-pretentious in the sense that 
and for 
. Thus, for instance, one had the logarithmically averaged two-point Chowla conjecture 
, where 
and all integers 
(which, in the odd order case, are no longer required to be distinct). (Superficially, this looks like we have resolved “half of the cases” of the logarithmically averaged Chowla conjecture; but it seems the odd order correlations are significantly easier than the even order ones. For instance, because of the Katai-Bourgain-Sarnak-Ziegler criterion, one can basically deduce the odd order cases of 
, unless the product 
weakly pretends to be a Dirichlet character 
in the sense that 
(which can be guaranteed if we pass to a suitable subsequence), then 
, each of which is 
whenever 
are integers with 
coprime to the periods of 
, but does put significant constraints on how these correlations may vary with 
.
possible length four sign patterns 
of the Liouville function occur with positive density, and all 
possible length four sign patterns 
occur with the conjectured logarithmic density. (In a 
and observe that 
for any 
, we obtain 
and 
is negligible in the limit (here is where we crucially rely on the log-averaging), hence 
behave like independent random variables as 
equipped with a measure-preserving invertible map 
. Using results of 
is a nilsequence, and 
goes to zero in density (even along the primes, or constant multiples of the primes). The original work of Bergelson-Host-Kra required ergodicity on 
, which is very definitely a hypothesis that is not available here; however, the later work of Leibman removed this hypothesis, and the work of Le refined the control on 
, we can now combine 
and an “irrational” or “minor arc” piece 
. The contribution of the minor arc piece 
-trick”, as well as known facts about the Gowers uniformity of the von Mangoldt function, one can obtain an approximation of the form 
. On the other hand, by iterating 
, and by again averaging over semiprimes one can obtain an approximation of the form 
. (This argument is not given in the current paper, but we plan to detail it in a subsequent one.)
of 
and degree 
can be defined as
is a positive definite quadratic form, since it has the sum of squares representation
unless 
. This can be compared against the superficially similar quadratic form
are independent randomly chosen signs. The Wigner semicircle law says that for large ![{[-\sqrt{n}, \sqrt{n}]}](https://s0.wp.com/latex.php?latex=%7B%5B-%5Csqrt%7Bn%7D%2C+%5Csqrt%7Bn%7D%5D%7D&bg=ffffff&fg=000000&s=0 "{[-\sqrt{n}, \sqrt{n}]}")
using the semicircle distribution, so in particular the form is quite far from being positive definite despite the presence of the first 
in that case. But one could hope for instance that
, let 
be even, and let 
, with strict inequality unless 
whenever 
, with equality if and only if 
, one has 
, with strict inequality unless 
.
, and easily verified for 
, so suppose that 
and the claims (i), (ii), (iii) have already been proven for 
(and for arbitrary 
to 
using the product rule, one obtains after a brief calculation
coefficient, we obtain the identity
by an arbitrary symmetric, continuously differentiable function. To establish this criterion, we induct on 
and 
we may assume that 
is majorised by 
, and 
is majorised by 
for some 
, and the claim then follows from two applications of the induction hypothesis. If instead 
, where 
is the arithmetic mean of 
is clearly a positive multiple of 
, and the claim now follows from (ii). 
, is a mixed blessing. At first, it causes unsuspecting undergrads (me) some angst via the Schrodinger’s cat paradox. This angst morphs into full-fledged panic when they encounter concepts such as nonlocality and Bell’s theorem (which, by the way, is surprisingly hard to 
Brawn
particles interacting via the Heisenberg Hamiltonian. Solving this system is not difficult so I was able to focus on fitting the two disparate parts – machine learning and Matrix Product States – together.
corresponds to some particle configuration indexed by 
of energy, particles occupy certain sites and might not occupy others. If the system has a different amount 
of energy, particles occupy different sites.
encodes the energies 
with a matrix, a square grid of numbers.
. We could calculate the system’s heat capacity, the energy required to raise the chunk’s temperature by one Kelvin. We could calculate 
. We would sum the weights: 
.
denote the number of qubits in the chunk. If 
dimensions, the classical system has 
dimensions. Suppose, for example, that our sites form a line. The classical system forms a square.
constant. 
units, to its, clearly more natural, measure in dollar units. A baby eats about 1000kCal/day=4200kJ/day. To fully deal with the consequences, we need a housekeeper to visit about once a week. 4200kJ/day times 7 days=29400 kJoules. These are consumed at T=300K. So an entropy of S=Q/T~100J/K, which is also S~
in dimensionless units, converts to S~$120, which is the cost of our weekly housekeeper visit. This gives a value of $ 
per entropy of a two-level system. Quite a reasonable bang for the buck, don’t you think?
Q/T. Why does the conjecture fail? Babies are not ‘maximal’. Consider presidents. Consider the mess that the government can make. It is at the scale of trillions per year. $ 
. Using the rigorous conversion rule established above, this corresponds to 
two-level systems. Which happens to quite precisely match the combined number of electrons present in the human bodies of all our military personnel. But the mess, however, is created by very few individuals.
, here we try to embed dynamical systems into the incompressible Euler equations 
. (One is particularly interested in the case of flat manifolds 
, particularly 
or 
, but for the main result of this paper it is essential that one is permitted to consider curved manifolds.) This system, first 
is the unknown solution, and 
is a bilinear map, which we may assume without loss of generality to be symmetric. One can ask whether such an ODE may be linearly embedded into the Euler equations on some Riemannian manifold 
from 
to smooth vector fields on 
to smooth scalar fields on 
takes solutions to 
.
on 
, with a funny metric on it that depends on 
by partially reformulating the Euler equations 
(which is a 
, chosen uniformly from all such sequences. A die 
if the number of pairs 
such that 
exceeds the number of pairs 
. If the two numbers are the same, we say that 
and 
.
to 
mod 
, and arrows into 
. It is not hard to check that the probability that there is an arrow from 
given that there are arrows from 
and ![A=(a_1,\dots,a_n)\in[n]^n](https://s0.wp.com/latex.php?latex=A%3D%28a_1%2C%5Cdots%2Ca_n%29%5Cin%5Bn%5D%5En&bg=ffffff&fg=333333&s=0 "A=(a_1,\dots,a_n)\in[n]^n")
we define a function ![f_A:[n]\to[n]](https://s0.wp.com/latex.php?latex=f_A%3A%5Bn%5D%5Cto%5Bn%5D&bg=ffffff&fg=333333&s=0 "f_A:[n]\to[n]")
by setting 
such that 
plus half the number of 
. We also define 
to be 
. It is not hard to verify that 
, ties with 
, and loses to 
.
. What is the probability that 
by 
. We can then ask it as follows. Suppose we choose a sequence 
of 
, where the terms of the sequence are independent and uniformly distributed. For each 
. What is the probability that 
given that 
?
, where the 
are i.i.d. random variables taking values in 
(at least if 
, it ought to be the case that if we sum up the probabilities that 
over positive 
of size comparable to the standard deviation. It will not tell you the probability of belonging to some subset of the y-axis (even for discrete random variables). Another problem is that the central limit on its own does not give information about the rate of convergence to a Gaussian, whereas here we require one.
when 
converges very well after 
. This we achieved in a slightly wasteful way — but the cost was a log factor that we could afford — by arguing that with high probability no value of 
. To prove this the steps were as follows.
is at most 
(for some 
is at least 
for some absolute constant 
.
for every 
to be
is shorthand for 
, ![f(x,y)=\mathbb P[(U,V)=(x,y)]](https://s0.wp.com/latex.php?latex=f%28x%2Cy%29%3D%5Cmathbb+P%5B%28U%2CV%29%3D%28x%2Cy%29%5D&bg=ffffff&fg=333333&s=0 "f(x,y)=\mathbb P[(U,V)=(x,y)]")
, and 
and 
range over 
.
not to be too close to 1. But for now I want to concentrate on how one proves a statement like this, since that is perhaps the least standard part of the argument.
to be very close to 1. This condition basically tells us that 
is highly concentrated mod 1: indeed, if 
takes approximately the same value almost all the time, so the average is roughly equal to that value, which has modulus 1; conversely, if 
are reasonably spread about. 
, let 
be of order of magnitude 
, and consider the values of 
and 
. Then a typical order of magnitude of 
is around 
, and one can prove without too much trouble (here the Berry-Esseen theorem was helpful to keep the proof short) that the probability that 
, for some positive absolute constant 
and applying the above argument in each interval. (While writing this I’m coming to think that I could just as easily have gone for progressions of length 3, not that it matters much.) Then in each interval there is a reasonable probability of getting the above inequality to hold many times, from which one can prove that with very high probability it holds many times. 
is of order 1, which gives that the values 
are far from constant whenever the above inequality holds. So by averaging we end up with a good upper bound for 
, then the above argument doesn’t work, because we can’t choose 
, the logarithmic factor being there because we need to operate in many different intervals in order to get the probability to be high. We will get many quadruples where 
of order 
, basically because 
has order 
for small 
. This is a good bound for us as long as we can use it to prove that 
is bounded above by a large negative power of 
(since 
is about 
), so we are in good shape provided that 
.
of the events hold is exponentially small in 
. A simpler argument of a similar flavour shows that 
is smaller than this and 
.
(which are independent and each have characteristic function 
) is 
. And then the inversion formula tells us that![\mathbb P[(\sum_iU_i,\sum_iV_i)=(x,y)]=\int_{(\alpha,\beta)\in\mathbb T^2}\hat f(\alpha,\beta)^ne(-\alpha x-\beta y)\mathop{d\alpha}\mathop{d\beta}](https://s0.wp.com/latex.php?latex=%5Cmathbb+P%5B%28%5Csum_iU_i%2C%5Csum_iV_i%29%3D%28x%2Cy%29%5D%3D%5Cint_%7B%28%5Calpha%2C%5Cbeta%29%5Cin%5Cmathbb+T%5E2%7D%5Chat+f%28%5Calpha%2C%5Cbeta%29%5Ene%28-%5Calpha+x-%5Cbeta+y%29%5Cmathop%7Bd%5Calpha%7D%5Cmathop%7Bd%5Cbeta%7D&bg=ffffff&fg=333333&s=0 "\mathbb P[(\sum_iU_i,\sum_iV_i)=(x,y)]=\int_{(\alpha,\beta)\in\mathbb T^2}\hat f(\alpha,\beta)^ne(-\alpha x-\beta y)\mathop{d\alpha}\mathop{d\beta}")
that lie outside a small rectangle (of width 
in the 
in the 
and the bound on 
,
this is 
. It therefore follows from the two-dimensional version of Taylor’s theorem that
that can be bounded above by a constant times 
.
for 
we have that 
is a positive semidefinite quadratic form in 
, and provided 
is small enough, 
is well approximated by 
. 
is very well approximated, at least when 
.
.)
