Riemann–Lebesgue lemma explained

In mathematics, the Riemann–Lebesgue lemma, named after Bernhard Riemann and Henri Lebesgue, states that the Fourier transform or Laplace transform of an L1 function vanishes at infinity. It is of importance in harmonic analysis and asymptotic analysis.

Statement

Let

f\inL1(\Rn)

be an integrable function, i.e.

f\colon\Rn\C

is a measurable function such that
\|f\|
L1

=

\int
\Rn

|f(x)|dx<infty,

and let

\hat{f}

be the Fourier transform of

f

, i.e.

\hat{f}\colon\Rn\C,\xi\mapsto

\int
\Rn

f(x)e-ix\xidx.

Then

\hat{f}

vanishes at infinity:

|\hat{f}(\xi)|\to0

as

|\xi|\toinfty

.

Because the Fourier transform of an integrable function is continuous, the Fourier transform

\hat{f}

is a continuous function vanishing at infinity. If
n)
C
0(\R
denotes the vector space of continuous functions vanishing at infinity, the Riemann–Lebesgue lemma may be formulated as follows: The Fourier transformation maps

L1(\Rn)

to
n)
C
0(\R
.

Proof

We will focus on the one-dimensional case

n=1

, the proof in higher dimensions is similar. First, suppose that

f

is continuous and compactly supported. For

\xi0

, the substitution

stylex\tox+

\pi
\xi
leads to

\hat{f}(\xi)=\int\Rf(x)e-ix\xidx=\int\Rf\left(x+

\pi
\xi

\right)e-ix\xie-i\pidx=-\int\Rf\left(x+

\pi
\xi

\right)e-ix\xidx

.This gives a second formula for

\hat{f}(\xi)

. Taking the mean of both formulas, we arrive at the following estimate:

|\hat{f}(\xi)|\le

1
2

\int\R\left|f(x)-f\left(x+

\pi
\xi

\right)\right|dx

.Because

f

is continuous,

\left|f(x)-f\left(x+\tfrac{\pi}{\xi}\right)\right|

converges to

0

as

|\xi|\toinfty

for all

x\in\R

. Thus,

|\hat{f}(\xi)|

converges to 0 as

|\xi|\toinfty

due to the dominated convergence theorem.

If

f

is an arbitrary integrable function, it may be approximated in the

L1

norm by a compactly supported continuous function. For

\varepsilon>0

, pick a compactly supported continuous function

g

such that
\|f-g\|
L1

\leq\varepsilon

. Then

\limsup\xi\pminfty|\hat{f}(\xi)|\leq\limsup\xi\to\pminfty\left|\int(f(x)-g(x))e-ix\xidx\right|+\limsup\xi\pminfty\left|\intg(x)e-ix\xidx\right|\leq\varepsilon+0=\varepsilon.

Because this holds for any

\varepsilon>0

, it follows that

|\hat{f}(\xi)|\to0

as

|\xi|\toinfty

.

Other versions

The Riemann–Lebesgue lemma holds in a variety of other situations.

f\inL1[0,infty)

, then the Riemann–Lebesgue lemma also holds for the Laplace transform of

f

, that is,
infty
\int
0

f(t)e-tzdt\to0

as

|z|\toinfty

within the half-plane

Re(z)\geq0

.

f

is an integrable function on a bounded interval, then the Fourier coefficients

\hat{f}k

of

f

tend to 0 as

k\to\pminfty

. This follows by extending

f

by zero outside the interval, and then applying the version of the Riemann–Lebesgue lemma on the entire real line.

Applications

The Riemann–Lebesgue lemma can be used to prove the validity of asymptotic approximations for integrals. Rigorous treatments of the method of steepest descent and the method of stationary phase, amongst others, are based on the Riemann–Lebesgue lemma.

References