Vinogradov's mean-value theorem explained

In mathematics, Vinogradov's mean value theorem is an estimate for the number of equal sums of powers.It is an important inequality in analytic number theory, named for I. M. Vinogradov.

More specifically, let

J_s,k(X)

count the number of solutions to the system of

simultaneous Diophantine equations in

variables given by

	j
x
	s

(1\lej\lek)

with

1\lex_i,y_i\leX,(1\lei\les)

.That is, it counts the number of equal sums of powers with equal numbers of terms (

) and equal exponents (

),up to

th powers and up to powers of

. An alternative analytic expression for

J_s,k(X)

J_s,k

(X)=\int
	[0,1)^k

	2s
\|f
	k(\alpha;X)\|

d\alpha

where

f_{k(\alpha;X)=\sum}_1\le\exp(2\pii(\alpha_{1x+ … +\alpha}

	k)).

	kx

Vinogradov's mean-value theorem gives an upper bound on the value of

J_s,k(X)

A strong estimate for

J_s,k(X)

is an important part of the Hardy-Littlewood method for attacking Waring's problem and also for demonstrating a zero free region for the Riemann zeta-function in the critical strip.^[1] Various bounds have been produced for

J_s,k(X)

, valid for different relative ranges of

and

. The classical form of the theorem applies when

is very large in terms of

An analysis of the proofs of the Vinogradov mean-value conjecture can be found in the Bourbaki Séminaire talk by Lillian Pierce.^[2]

Lower bounds

By considering the

X^s

solutions where

x_i=y_i,(1\lei\les)

one can see that

J_s,k(X)\ggX^s

A more careful analysis (see Vaughan ^[3] equation 7.4) provides the lower bound

J_s,k\ggX^s+X

2s-	12k(k+1)

Proof of the Main conjecture

The main conjecture of Vinogradov's mean value theorem was that the upper bound is close to this lower bound. More specifically that for any

\epsilon>0

we have

J_s,k(X)\llX^s+\epsilon

2s-	12k(k+1)+\epsilon

This was proved by Jean Bourgain, Ciprian Demeter, and Larry Guth^[4] and by a different method by Trevor Wooley.^[5]

s\ge

	12k(k+1)

this is equivalent to the bound

J_s,k(X)\ll

2s-	12k(k+1)+\epsilon

Similarly if

s\le

	12k(k+1)

the conjectural form is equivalent to the bound

J_s,k(X)\llX^s+\epsilon.

Stronger forms of the theorem lead to an asymptotic expression for

J_s,k

, in particular for large

relative to

the expression

J_s,k\sim

2s-	12k(k+1)

lC(s,k)X

where

lC(s,k)

is a fixed positive number depending on at most

and

, holds, see Theorem 1.2 in.^[6]

History

Vinogradov's original theorem of 1935 ^[7] showed that for fixed

s,k

with

s\gek^2log

2+k)+

14k

2+	54
	k+1

there exists a positive constant

D(s,k)

such that

J_s,k(X)\leD(s,k)(logX)^2s

2s-

12k(k+1)+	12

Although this was a ground-breaking result, it falls short of the full conjectured form. Instead it demonstrates the conjectured form when

\epsilon>	12

Vinogradov's approach was improved upon by Karatsuba^[8] and Stechkin^[9] who showed that for

s\gek

there exists a positive constant

D(s,k)

such that

J_s,k(X)\le

2s-	12k(k+1)+η
	_s,k

D(s,k)X

where

η_s,k=

	12
	k

2\left(1-

1k\right)

\left[	sk\right]

\lek^2e

	-s/k²

Noting that for

s>k^2(2logk-log\epsilon)

we have

η_s,k<\epsilon

this proves that the conjectural form holds for

of this size.

The method can be sharpened further to prove the asymptotic estimate

J_s,k\sim

2s-	12k(k+1)

lC(s,k)X

for large

in terms of

In 2012 Wooley^[10] improved the range of

for which the conjectural form holds. He proved that for

k\ge2

and

s\gek(k+1)

and for any

\epsilon>0

we have

J_s,k(X)\ll

2s-	12k(k+1)+\epsilon

Ford and Wooley^[11] have shown that the conjectural form is established for small

in terms of

. Specifically they show that for

k\ge4

and

1\les\le

	14(k+1)
	²

for any

\epsilon>0

we have

J_s,k(X)\llX^s+\epsilon.

Notes and References

Book: Titchmarsh, Edward Charles . Edited and with a preface by D. R. Heath-Brown . The theory of the Riemann Zeta-function . Second . 1986 . 0882550 . The Clarendon Press, Oxford University Press . New York . 978-0-19-853369-6 .
Lilian B. . Pierce. Lillian Pierce. The Vinogradov mean-value theorem [after Wooley, and Bourgain, Demeter and Guth] . 2017. 69. 1134 . 1–80 . 1707.00119 . Séminaire Bourbaki.
Book: Vaughan, Robert C. . The Hardy-Littlewood method . 1997 . 25 . Second . Cambridge Tracts in Mathematics . Cambridge . Cambridge University Press . 978-0-521-57347-4 . 1435742.
Jean . Bourgain . Ciprian . Demeter . Larry . Guth . Proof of the main conjecture in Vinogradov's Mean Value Theorem for degrees higher than three . 2016. 184. 2 . 10.4007/annals.2016.184.2.7 . 633–682 . 1512.01565 . Ann. of Math.. 1721.1/115568 . 43929329 .
10.1112/plms.12204. free. Nested efficient congruencing and relatives of Vinogradov's mean value theorem. 2019. Wooley. Trevor D.. Proceedings of the London Mathematical Society. 118. 4. 942–1016. 1708.01220.
10.4007/annals.2012.175.3.12. free. Vinogradov's mean value theorem via efficient congruencing. 2012. Wooley. Trevor. Annals of Mathematics. 175. 3. 1575–1627. 1101.0574.
I. M. Vinogradov, New estimates for Weyl sums, Dokl. Akad. Nauk SSSR 8 (1935), 195–198
Anatoly . Karatsuba . Mean value of the modulus of a trigonometric sum. Izv. Akad. Nauk SSSR Ser. Mat. . 37 . 1973 . 6 . 1203–1227 . 10.1070/IM1973v007n06ABEH002080 . 1973IzMat...7.1199K . 0337817 . ru.
Sergeĭ Borisovich . Stečkin . Mean values of the modulus of a trigonometric sum . Trudy Mat. Inst. Steklov . 134 . 1975 . 283–309 . 0396431 . ru.
Trevor D. . Wooley . Vinogradov's mean value theorem via efficient congruencing . . 175 . 2012 . 1575–1627 . 10.4007/annals.2012.175.3.12 . 2912712 . 3. 1101.0574 . 13286053 .
Kevin . Ford . Trevor D. . Wooley . On Vinogradov's mean value theorem: strong diagonal behaviour via efficient congruencing . 10.1007/s11511-014-0119-0 . . 2014 . 213 . 2 . 199–236 . 3286035. 1304.6917 . 11603320 .