An almost integer is a number that is very close to an integer.
Near-solutions to Fermat's last theorem provide a number of high-profile almost integers. In the season 7, episode 6 ("Treehouse
of Horror VI") segment entitled 
of the animated televsion program The Simpsons,
the equation 
appears at one point in the background. Expansion reveals that only the first 9 decimal
digits match (Rogers 2005). Simpsons season 10, episode 2 ("The Wizard
of Evergreen Terrace") mentions 
, which matches not only in the
first 10 decimal places but also the easy-to-check last place (Greenwald). The corresponding
almost integers are
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(1)
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(2)
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Some surprising almost integers are given by
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(3)
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which equals 
to within 5 digits and
![sin(2017RadicalBox[2, 5])=-0.9999999999999999785...,](/images/equations/AlmostInteger/NumberedEquation2.svg) |
(4)
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which equals 
to within 16 digits (M. Trott, pers. comm., Dec. 7, 2004). The first of
these comes from the half-angle formula identity
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(5)
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where 22 is the numerator of the convergent 22/7 to 
, so 
. It therefore follows
that any pi approximation 
gives a near-identity of the form 
.
Another surprising example involving both e and pi is
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(6)
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(cf. Maze and Minder 2005), which can also be written as
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(7)
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(8)
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Here, 
is Gelfond's constant. This near-identity was
apparently noticed almost simultaneously around 1988 by N. J. A. Sloane,
J. H. Conway, and S. Plouffe. Its origins can be connected to the
sum related to Jacobi theta functions
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(9)
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The first term dominates since the other terms contribute only
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(10)
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giving
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(11)
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Rewriting as
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(12)
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and using the approximation 
then gives
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(13)
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(A. Doman, Sep. 18, 2023; communicated by D. Bamberger, Nov. 26, 2023). Amusingly, the choice of 
(which is not mathematically significant compared
to other choices except that it makes the final form very simple) in the last step
makes the formula an order of magnitude more precise than it would otherwise be.
The near-identify can be made even closer by applying cosine a few more times, e.g.,
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(14)
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Another nested cosine almost integer is given by
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(15)
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(P. Rolli, pers. comm., Feb. 19, 2004).
An example attributed to Ramanujan is
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(16)
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Some near-identities involving integers and the logarithm are
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(17)
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(18)
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(19)
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which are good to 6, 6, and 6 decimal digits, respectively (K. Hammond, pers. comm., Jan. 4 and Mar. 23-24, 2006).
An interesting near-identity is given by
![1/4[cos(1/(10))+cosh(1/(10))+2cos(1/(20)sqrt(2))cosh(1/(20)sqrt(2))]=1+2.480...×10^(-13)](/images/equations/AlmostInteger/NumberedEquation13.svg) |
(20)
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(W. Dubuque, pers. comm.).
Near-identities involving 
and 
are given by
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(21)
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(D. Wilson, pers. comm.),
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(22)
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(D. Ehlke, pers. comm., Apr. 7, 2005),
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(23)
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(Povolotsky, pers. comm., May 11, 2008), and
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(24)
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(good to 8 digits; M. Stay, pers. comm., Mar. 17, 2009), or equivalently
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(25)
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Other remarkable near-identities are given by
![(5(1+sqrt(5))[Gamma(3/4)]^2)/(e^(5pi/6)sqrt(pi))=1+4.5422...×10^(-14),](/images/equations/AlmostInteger/NumberedEquation19.svg) |
(26)
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where 
is the gamma function (S. Plouffe, pers. comm.),
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(27)
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(D. Davis, pers. comm.),
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(28)
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(posted to sci.math; origin unknown),
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(29)
|
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(30)
|
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(31)
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where 
is Catalan's constant, 
is the Euler-Mascheroni
constant, and 
is the golden ratio (D. Barron, pers. comm.),
and
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(32)
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(33)
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![[(2-1)^2+((5^2-1)^2)/(6^2+1)]e-[(2+1)^2+((5^2+1)^2)/(6^2-1)]^(-1)](/images/equations/AlmostInteger/Inline40.svg) |  |  |
(34)
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(35)
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(E. Stoschek, pers. comm.). Stoschek also gives an interesting near-identity involving the fine structure constant 
and Feigenbaum constant 
,
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(36)
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E. Pegg Jr. (pers. comm., Mar. 4, 2002) discovered the interesting near-identities
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(37)
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and
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(38)
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The near-identity
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(39)
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arises by noting that the augmentation ratio 
in the augmentation
of the dodecahedron to form the great
dodecahedron is approximately equal to 
. Another near identity is given by
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(40)
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where 
is Apéry's constant and 
is the Euler-Mascheroni
constant, which is accurate to four digits (P. Galliani, pers. comm., April
19, 2002).
J. DePompeo (pers. comm., Mar. 29, 2004) found
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(41)
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which is equal to 1 to five digits.
M. Hudson (pers. comm., Oct. 18, 2004) noted the almost integer
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(42)
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where 
is Khinchin's constant, as well as
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(43)
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(pers. comm., Feb. 4, 2005), where 
is the Euler-Mascheroni
constant.
M. Joseph found
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(44)
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which is equal to 1 to four digits (pers. comm., May 18, 2006). M. Kobayashi (pers. comm., Sept. 17, 2004) found
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(45)
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which is equal to 1 to five digits. The related expression
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(46)
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which is equal to 0 to six digits (E. Pegg Jr., pers. comm., Sept. 28, 2004). S. M. Edde (pers. comm., Sep. 7, 2007) noted that
![exp[-psi_0(1/4(2+sqrt(3)))]=1.99999969...,](/images/equations/AlmostInteger/NumberedEquation38.svg) |
(47)
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where 
is the digamma function.
E. W. Weisstein (Mar. 17, 2003) found the almost integers
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(48)
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(49)
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(50)
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as individual integrals in the decomposition of the integration region to compute the average area of a triangle in triangle triangle picking.
and 
give the almost integer
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(51)
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(E. W. Weisstein, Feb. 5, 2005).
Prudnikov et al. (1986, p. 757) inadvertently give an almost integer result by incorrectly identifying the infinite product
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(52)
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where 
is a q-Pochhammer symbol, as being
equal 
,
which differs from the correct result by
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(53)
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A much more obscure almost identity related to the eight curve is the location of the jump in
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(54)
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where
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(55)
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and 
is an elliptic integral of the third
kind, which is 1.3333292798..., or within 
of 4/3 (E. W. Weisstein, Apr. 2006).
Another slightly obscure one is the value of 
needed to give a 99.5% confidence
interval for a Student's t-distribution
with sample size 30, which is 2.7499956..., or within
of 11/4 (E. W. Weisstein,
May 2, 2006).
Let 
be the average length of a line in triangle line
picking for an isosceles right triangle,
then
![l^_=1/(30)[2+4sqrt(2)+(4+sqrt(2))sinh^(-1)1] approx 0.4142933026,](/images/equations/AlmostInteger/NumberedEquation44.svg) |
(56)
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which is within 
of 
.
D. Terr (pers. comm., July 29, 2004) found the almost integer
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(57)
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where 
is the golden ratio and 
is the natural logarithm
of 2.
A set of almost integers due to D. Hickerson are those of the form
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(58)
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for 
,
as summarized in the following table.
 |  |
| 0 | 0.72135 |
| 1 | 1.04068 |
| 2 | 3.00278 |
| 3 | 12.99629 |
| 4 | 74.99874 |
| 5 | 541.00152 |
| 6 | 4683.00125 |
| 7 | 47292.99873 |
| 8 | 545834.99791 |
| 9 | 7087261.00162 |
| 10 | 102247563.00527 |
| 11 | 1622632572.99755 |
| 12 | 28091567594.98157 |
| 13 | 526858348381.00125 |
| 14 | 10641342970443.08453 |
| 15 | 230283190977853.03744 |
| 16 | 5315654681981354.51308 |
| 17 | 130370767029135900.45799 |
These numbers are close to integers due to the fact that the quotient is the dominant term in an infinite series for the number of possible outcomes of a race between
people (where ties are allowed). Calling
this number 
,
it follows that
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(59)
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with 
,
where 
is a binomial coefficient. From this, we
obtain the exponential generating function
for 
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(60)
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and then by contour integration it can be shown that
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(61)
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for 
,
where 
is the square root of 
and the sum is over all integers 
(here, the imaginary parts of the terms for 
and 
cancel each other, so this sum is real). The 
term dominates, so 
is asymptotic to 
. The sum can be done explicitly as
![f(n)=((-1)^(n+1)in!)/(pi^(n+1)2^(n+2))[i^nzeta(n+1,1+(iln2)/(2pi))-(-i)^nzeta(n+1,-(iln2)/(2pi))],](/images/equations/AlmostInteger/NumberedEquation50.svg) |
(62)
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where 
is the Hurwitz zeta function. In fact, the
other terms are quite small for 
from 1 to 15, so 
is the nearest integer to 
for these values, given by the sequence 1,
3, 13 75, 541, 4683, ... (OEIS A034172).
A large class of irrational "almost integers" can be found using the theory of modular functions,
and a few rather spectacular examples are given by Ramanujan (1913-14). Such approximations
were also studied by Hermite (1859), Kronecker (1863), and Smith (1965). They can
be generated using some amazing (and very deep) properties of the j-function.
Some of the numbers which are closest approximations to integers
are 
(sometimes known as the Ramanujan constant
and which corresponds to the field 
which has class number
1 and is the imaginary quadratic field
of maximal discriminant), 
, 
, and 
, the last three of which have class
number 2 and are due to Ramanujan (Berndt 1994, Waldschmidt 1988ab).
The properties of the j-function also give rise to the spectacular identity
![[(ln(640320^3+744))/pi]^2=163+2.32167...×10^(-29)](/images/equations/AlmostInteger/NumberedEquation51.svg) |
(63)
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(Le Lionnais 1983, p. 152; Trott 2004, p. 8).
The list below gives numbers of the form 
for 
for which 
.
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| 25 |  |
| 37 |  |
| 43 |  |
| 58 |  |
| 67 |  |
| 74 |  |
| 148 | 0.00097 |
| 163 |  |
| 232 |  |
| 268 | 0.00029 |
| 522 |  |
| 652 |  |
| 719 |  |
Gosper (pers. comm.) noted that the expression
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(64)
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differs from an integer by a mere 
.
E. Pegg Jr. noted that the triangle dissection illustrated above has length
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(65)
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(66)
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which is almost an integer.
Borwein and Borwein (1992) and Borwein et al. (2004, pp. 11-15) give examples of series identities that are nearly true. For example,
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(67)
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which is true since 
and 
for positive integer 
.
In fact, the first few doubled values of 
at which 
are 268, 536, 804, 1072, 1341, 1609,
...(OEIS A096613).
An example of a (very) near-integer is
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(68)
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(69)
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(Borwein and Borwein 1992; Maze and Minder 2005).
Maze and Minder (2005) found the class of near-identities obtained from
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(70)
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as
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(71)
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(72)
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(73)
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(74)
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(75)
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(76)
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(77)
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(78)
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(OEIS A114609 and A114610). Here, the excesses can be computed as exact sums connected by a recurrence relation, with the first few being
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(79)
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(80)
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(Maze and Minder 2005). These sums can also be done in closed form using q-polygamma functions 
,
giving for example
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(81)
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(82)
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with 
.
An amusing almost integer involving units of length is given by
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(83)
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and one involving lengths, time, and speed is given by
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(84)
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(J. Martin-Garcia, pers. comm., Jun 25, 2022).
If combinations of physical and mathematical constants are allowed and taken in SI units, the following quantities have a near-integer numeric prefactor
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(85)
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(86)
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(M. Trott, pers. comm. Apr. 28, 2011), the first of which was apparently noticed by Weisskopf. Here, 
is the speed of light, 
is the elementary charge, 
is Boltzmann's constant, 
is Planck's constant, 
is the bond percolation threshold for a 4-dimensional hypercube
lattice, 
is the vacuum permittivity, and 
is the Rydberg constant. Another famous example of this
sort is Wyler's constant, which approximates the
(dimensionless) fine structure constant in terms of fundamental mathematical constants.
--Mathematics in the Year 3000." 
." Quart. J. Pure Appl. Math. 45,
350-372, 1913-14.Roberts, J. 