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On periodic solutions of a certain nonlinear equation
ON PERIODIC SOLUTIONS OF A CERTAIN NONLINEAR EQUATION (0 PERIODICAESKOM
ODNOQO NELINEINOGO
RESAENII URAVNENIIA)
PMM Vo1.27,
1963,
No.6, I.D.
pp.f107-iii0
KILL’
(Yoscor) (Received
The Question dlz x2 is
This
existence
dz ecostdt+
of
periodic
is
I and -z,
be odd in t.
[d
Cesari’s
invariant
with
(1)
Consider val
[O,
2~1,
the
space
which
respect
equation
[21
(O
(1)
to
the
its
simultaneous
solution
inter-
may supposed
may be rewritten = 4e sin 1
p
S of
are
of
method.
gd- i -S_c~~~s~sin 1 + Tcosl z +
solutions
and hence
and t and -t,
Equation
1963)
4e sin t z = 1 + ecost
1 +:cosrein
by means of
equation of
the
23,
2e sin t
1+
considered
change to
of
May
functions
of
odd and periodic
(,z = 1 + 2 e cos t )
integrable with
sauare
period
2v,
on the
(2)
inter-
endowed with
the
norm v (a$ = [$G
(I) dl]lif
(3)
0 For x in S,
we have 2-
2
v (z) = i;;
b, sin kt,
k=l
Consider,
in the
space
&I’*
(4)
k-l
S,
the
linear
Pz = b, sin t + b, sin 21,
operator la
Hz = -
1699
P and H such
x ke2b, sin lit h’_=l
that (5)
I.D.
1700
If
A
Kill’
then
E 0,
cu
2
2
(t)-
b, siu kt,
(6)
Ii-n Now consider Qz._?._!?c-
Let
1 f
k=n
the
e cos t
operators
z -
p sin -L-y--+
1 $-
X* be a function Px*
Q and F
e co5
4e sin t,
i
Fz
H(Qs--PQz)
=
(7)
such that
=
x* 7
t + b, sin 2t
b, sin
(x* ES)
(8)
Then v (x*)
Consider s*=
the
2-‘I’
=
subset
(b,2 +
b,2)liz < c
(c =
const)
(9)
S*
[Z,2ES,Px=z*,
Y(Z)
v(x-
x*) <‘a!
(d, 6 =
For arbitrary values of the constants d and 6, the subset since each X* belongs to S*. The space s is complete,
empty, closed;
consequently,
Following
S* is
hl . let
us
a complete
introduce
const~
S* is not and S* is
space.
the
operator
T
y=Tx==Px+Fx-Px+H(Qx-PQx)
If
x is
in S*,
PFx
employing
(6), v (y -
Employing
the
obvious
readily
If(Qx.
3-’ v (Qr -
P Qx)
PQ4
-
(12)
we obtain Py)
d
ZJZ)< v (z),
(13)
2 E “7
e
ecos (-j-.qcost
cos t
l+ecostP’-P (z -
-
y-Py-m
that
v(Qx--PQx)
px x*,
inequality v (2 -
one obtains
(11)
then
Py = PPT +
From this,
(W
Pz)]
-I- pv
[sin j:~&~]
Ti2 (b,, b,. e) -I- 7s * (b,, b,, 4 “’ I
2
p.,]
__+
< [F (b,, bz, e) es +,_,+p
(14)
Here F (b,, b,, e) = 2; \ @* (t) dt iJ
(Q,
(1) =
e (1
.+
cos t e
cos
t)
x* (4 )
Periodic
solutrons
a certain
of
nonltnear
where y1 and y2 are the coefficients of sin t and of sin 2t Fourier expansion of the function a(t). Now suppose that the coefficients the inequal it ies
lhl
IhI
and b,
bl
of equation
(al, a,
1701
equation
in the
(8)
satisfy
= const)
(15)
Then we may put c
From (14)
we obtain
2-‘/Q(al”
=
(16)
that -r12f
v(Qr-PQz)
a,“)‘/’
+
the closed
rectangle
2
1
722 ‘1s
in the bl,
(17)
space which is defined
b,
by
(15). In order
that y belong
to SO, it
v(Y----Y)
The first
of relations
is obviously
will
sufficient
that
d==c+-S
(18)
be fulfilled,
provided
that
(1% If
(19) holds
for
a certain
6 = 6,.
then,
upon setting
d=c+a,
(20)
we obtain T (S*) E S*
(21)
Let us prove that, in a certain range of values of the parameters u and e, the operator T is a contracting operator on S*. Writing y1 = Txl y2 = TX,, with XI and x2 in S, we obtain yl-yp=
v
Hence,
(~1 -
Qq)---P(Qq-
HI(Qq-
YA < 3-% [(Qrl -
Q4
- P (Qq -
Q41
Qzz)l Q 39 v (Qq -
44
if
(22)
I.D.
1702
then
is a contracting
T
Thus,
if
relations
in view of point x*,
(19)
Banach’s It
y in S*. and,
operator to
of
The right-hand
the
side
the
twice,
(2) +
P
6, +
and bp.
We have
of
(23)
is,
almost
t,
in view
has this
everywhere, of
a twice
hypothesis
Equations
(25)
coefficients
solution
of
solutions ities
bl
(15).
con-
H;
property.
we obtain
QY
-
PQY
=
4e -
of
L’
0,
[3-
9~ + J’
(2).
when P[d2y/dt2
46, +
: -
(24)
QY] -
(35)
(%a(b,, b,) = 0
sin ~1 dl
the
T,
- PQy)
is a periodic solution the same thing, when j31 (h,, 11,)-
the operator
[31, has a unique fixed a continuous function of
y is h,
(23)
also
then
theorem
that
function
(23)
The function y(t) F 0 or, which is 11 =: --
[d,
equation side
flY dt2
fulfilled,
PY -1 II (Q!/
left-hand
Differentiating
Qyl
of
are
mapping
coefficients
differentiable
sequently,
(22)
may be proved
!I
continuously
on S*.
contraction
therefore,
Kill’
(72
1,2)
may be regarded as equations for the determination of of the existence of a periodic and b2. The question to the question of the existence of reduces, therefore, b,
(2)
and b, Let
of
equations
us substitute
(25)
which
equations
also
(25)
satisfy
by the
the
inequal-
approximate
equa-
tions
?r:
2n
ecost
1 +ecost
Let plane
z* (t)
sin nt dt +
us map, by means of into
Let plane. system following
a domain
in the
sin
_k!-
formulas
5* 1 +
(26),
(t) ecost
the
sin nt df
domain D of
1, 2)
(n =
the
b,,
b,
l/V plane.
co be the boundary of the corresponding domain A0 in the UV If the origin of coordinates of the UV plane belongs to Ao, then (26)
has a solution inequality
satisfying
(15).
If,
in particular,
the
holds:
nlaxo v(CJ -
U,)* $- (V -
VJ2
[CO,01
(27)
Periodic
min [C,. 01 is
where to
a point
of
the mapping
(0,
solutions
of
the
for
O
the
parameters.
(19)
has the
a
distance
nonlinear
(25)
the
also
has a solution
question
of
the
and e = 0.6. Let
us choose
a1 = 3.5
A, also
coordinates as a result
contains
satisfies
of
periodic
(22)
of
obtained
which
existence
Condition
1703
equation
from the origin
c,,,
holds
for
and a2 = 0.5,
the
origin
(15). solutions these
then
values
of of
inequality
form 3-2 IO.415 +
and is
certain
then the domain D by means of formulas (25),
of
Now consider (2)
least
boundary
and hence
6).
the
of
fulfilled
for
d = 2.556
+ 0.134
hand side
of
8 = 0.056
p_ Let
1.58 $p]
+ 0.134
us estimate
< 6
(28)
CI. Equation the
quantity
(20)
then
appearing
gives on the
left-
(27)
1U -
U, ( =
] fll -
file 1 =
1f \ $$$;
(y -
Py) sin t dt +
il 273 +
+
5
2sin
0 Employing
the
Y + PY Y - PY cos sin t dt 2 (1 + e cos t) 2 (1 +- e cos 1) I
Cauchy-Buniakovskii
inequality
for
integrals,
we obtain
2rr $- k
(1
(y -
Pylz
dt)“’ (p
d
(~ ,“;;t
t)2 dt)“’ <
0 dt ‘I* )
Analogously,
it
follows
that sin2 2t
(1 Choosing and (39),
c = 0.6,
(2%
1
and calculating
the
integrals
(1 + e cos t)? appearing
dt
‘/I )I
in
(30)
(29)
we obtain
For p = 1,
from
(31)
it
follows
mas o d{uxT+
that (V -
V,)2 < 0.683
(32)
1704
I.D.
Let into
us map the
the
rectangle
W plane,
lb11
by means of
Kill’
3.5,
<
lb,1
formulas the
domain
curve
0.5,
<
(26),
for
(see
c,, (l),
of the bl, bp plane, CI = 1. Then we obtain
Figure),
bounded
by the
where
mirl IQ (11,01 > 0.780 From (32) and (33) equality (27) holds. If
we map the
cry plane,
again
we obtain
the
is
bounded
follows
that
same rectangle using
domain
by the
From the
it
(X,
(26)
Figure
it
Figure)
cc is
the
but with
(see
curve
into
in-
~1 = 0,
which
(0).
readily
seen
that
min [CO(I), 0,] < miri [co [O), 0] uO, V0 are
The quantities the
following
inequality
linear
functions
of
~1; hence,
for
(34) 0 <:cl%l,
holds: (35)
min [cO (I), 01 < min IQ (p), 01 On the
other
hand,
the
quantity
(31)
is
an increasing
function
(32)
is
also
true
for
all
that
(27)
holds
easily the
hence
equation
The mapping carried
out
(2) of
(27)
the
the
CI
and thus
11.From
b,,
b,
side
satisfying
of
inequality
this
and 0 < CI< 1. For these
has solutions
boundary
on the right-hand
0<
interval
e = 0.6
has periodic
by means of
~1 for
p in the for
system
parameters,
appearing
of
it
follows
values (15),
of and
solutions. of
the
computing
rectangle
into
machine
“Strela”.
the
UV plane
was
BIBLIOGRAPHY 1.
Cesari, L., Periodic Symposium on Active Brooklyn,
2.
Beletskii.
N. Y., V.V.,
Zskusstvennye
3.
Kantorovich, rovannykh
Fizmatgiz,
solutions
of
Networks
differential
and
Feedback
systems. Systems.
Proc.
New York,
1960;
1961. 0 libratsii sputnik;
L.V.
sputnika Zemli,
and Akilov,
prostranstvakh
(On librations
No. 3, G.P.,
(Functional
of
satellites).
1959.
Funktsional
Analysis
‘nyi
anal
in
Vormed
iz
v normi.spaces).
1959. Translated
by J.B.D.
ODNOQO NELINEINOGO
RESAENII URAVNENIIA)
PMM Vo1.27,
1963,
No.6, I.D.
pp.f107-iii0
KILL’
(Yoscor) (Received
The Question dlz x2 is
This
existence
dz ecostdt+
of
periodic
is
I and -z,
be odd in t.
[d
Cesari’s
invariant
with
(1)
Consider val
[O,
2~1,
the
space
which
respect
equation
[21
(O
(1)
to
the
its
simultaneous
solution
inter-
may supposed
may be rewritten = 4e sin 1
p
S of
are
of
method.
gd- i -S_c~~~s~sin 1 + Tcosl z +
solutions
and hence
and t and -t,
Equation
1963)
4e sin t z = 1 + ecost
1 +:cosrein
by means of
equation of
the
23,
2e sin t
1+
considered
change to
of
May
functions
of
odd and periodic
(,z = 1 + 2 e cos t )
integrable with
sauare
period
2v,
on the
(2)
inter-
endowed with
the
norm v (a$ = [$G
(I) dl]lif
(3)
0 For x in S,
we have 2-
2
v (z) = i;;
b, sin kt,
k=l
Consider,
in the
space
&I’*
(4)
k-l
S,
the
linear
Pz = b, sin t + b, sin 21,
operator la
Hz = -
1699
P and H such
x ke2b, sin lit h’_=l
that (5)
I.D.
1700
If
A
Kill’
then
E 0,
cu
2
2
(t)-
b, siu kt,
(6)
Ii-n Now consider Qz._?._!?c-
Let
1 f
k=n
the
e cos t
operators
z -
p sin -L-y--+
1 $-
X* be a function Px*
Q and F
e co5
4e sin t,
i
Fz
H(Qs--PQz)
=
(7)
such that
=
x* 7
t + b, sin 2t
b, sin
(x* ES)
(8)
Then v (x*)
Consider s*=
the
2-‘I’
=
subset
(b,2 +
b,2)liz < c
(c =
const)
(9)
S*
[Z,2ES,Px=z*,
Y(Z)
v(x-
x*) <‘a!
(d, 6 =
For arbitrary values of the constants d and 6, the subset since each X* belongs to S*. The space s is complete,
empty, closed;
consequently,
Following
S* is
hl . let
us
a complete
introduce
const~
S* is not and S* is
space.
the
operator
T
y=Tx==Px+Fx-Px+H(Qx-PQx)
If
x is
in S*,
PFx
employing
(6), v (y -
Employing
the
obvious
readily
If(Qx.
3-’ v (Qr -
P Qx)
PQ4
-
(12)
we obtain Py)
d
ZJZ)< v (z),
(13)
2 E “7
e
ecos (-j-.qcost
cos t
l+ecostP’-P (z -
-
y-Py-m
that
v(Qx--PQx)
px x*,
inequality v (2 -
one obtains
(11)
then
Py = PPT +
From this,
(W
Pz)]
-I- pv
[sin j:~&~]
Ti2 (b,, b,. e) -I- 7s * (b,, b,, 4 “’ I
2
p.,]
__+
< [F (b,, bz, e) es +,_,+p
(14)
Here F (b,, b,, e) = 2; \ @* (t) dt iJ
(Q,
(1) =
e (1
.+
cos t e
cos
t)
x* (4 )
Periodic
solutrons
a certain
of
nonltnear
where y1 and y2 are the coefficients of sin t and of sin 2t Fourier expansion of the function a(t). Now suppose that the coefficients the inequal it ies
lhl
IhI
and b,
bl
of equation
(al, a,
1701
equation
in the
(8)
satisfy
= const)
(15)
Then we may put c
From (14)
we obtain
2-‘/Q(al”
=
(16)
that -r12f
v(Qr-PQz)
a,“)‘/’
+
the closed
rectangle
2
1
722 ‘1s
in the bl,
(17)
space which is defined
b,
by
(15). In order
that y belong
to SO, it
v(Y----Y)
The first
of relations
is obviously
will
sufficient
that
d==c+-S
(18)
be fulfilled,
provided
that
(1% If
(19) holds
for
a certain
6 = 6,.
then,
upon setting
d=c+a,
(20)
we obtain T (S*) E S*
(21)
Let us prove that, in a certain range of values of the parameters u and e, the operator T is a contracting operator on S*. Writing y1 = Txl y2 = TX,, with XI and x2 in S, we obtain yl-yp=
v
Hence,
(~1 -
Qq)---P(Qq-
HI(Qq-
YA < 3-% [(Qrl -
Q4
- P (Qq -
Q41
Qzz)l Q 39 v (Qq -
44
if
(22)
I.D.
1702
then
is a contracting
T
Thus,
if
relations
in view of point x*,
(19)
Banach’s It
y in S*. and,
operator to
of
The right-hand
the
side
the
twice,
(2) +
P
6, +
and bp.
We have
of
(23)
is,
almost
t,
in view
has this
everywhere, of
a twice
hypothesis
Equations
(25)
coefficients
solution
of
solutions ities
bl
(15).
con-
H;
property.
we obtain
QY
-
PQY
=
4e -
of
L’
0,
[3-
9~ + J’
(2).
when P[d2y/dt2
46, +
: -
(24)
QY] -
(35)
(%a(b,, b,) = 0
sin ~1 dl
the
T,
- PQy)
is a periodic solution the same thing, when j31 (h,, 11,)-
the operator
[31, has a unique fixed a continuous function of
y is h,
(23)
also
then
theorem
that
function
(23)
The function y(t) F 0 or, which is 11 =: --
[d,
equation side
flY dt2
fulfilled,
PY -1 II (Q!/
left-hand
Differentiating
Qyl
of
are
mapping
coefficients
differentiable
sequently,
(22)
may be proved
!I
continuously
on S*.
contraction
therefore,
Kill’
(72
1,2)
may be regarded as equations for the determination of of the existence of a periodic and b2. The question to the question of the existence of reduces, therefore, b,
(2)
and b, Let
of
equations
us substitute
(25)
which
equations
also
(25)
satisfy
by the
the
inequal-
approximate
equa-
tions
?r:
2n
ecost
1 +ecost
Let plane
z* (t)
sin nt dt +
us map, by means of into
Let plane. system following
a domain
in the
sin
_k!-
formulas
5* 1 +
(26),
(t) ecost
the
sin nt df
domain D of
1, 2)
(n =
the
b,,
b,
l/V plane.
co be the boundary of the corresponding domain A0 in the UV If the origin of coordinates of the UV plane belongs to Ao, then (26)
has a solution inequality
satisfying
(15).
If,
in particular,
the
holds:
nlaxo v(CJ -
U,)* $- (V -
VJ2
[CO,01
(27)
Periodic
min [C,. 01 is
where to
a point
of
the mapping
(0,
solutions
of
the
for
O
the
parameters.
(19)
has the
a
distance
nonlinear
(25)
the
also
has a solution
question
of
the
and e = 0.6. Let
us choose
a1 = 3.5
A, also
coordinates as a result
contains
satisfies
of
periodic
(22)
of
obtained
which
existence
Condition
1703
equation
from the origin
c,,,
holds
for
and a2 = 0.5,
the
origin
(15). solutions these
then
values
of of
inequality
form 3-2 IO.415 +
and is
certain
then the domain D by means of formulas (25),
of
Now consider (2)
least
boundary
and hence
6).
the
of
fulfilled
for
d = 2.556
+ 0.134
hand side
of
8 = 0.056
p_ Let
1.58 $p]
+ 0.134
us estimate
< 6
(28)
CI. Equation the
quantity
(20)
then
appearing
gives on the
left-
(27)
1U -
U, ( =
] fll -
file 1 =
1f \ $$$;
(y -
Py) sin t dt +
il 273 +
+
5
2sin
0 Employing
the
Y + PY Y - PY cos sin t dt 2 (1 + e cos t) 2 (1 +- e cos 1) I
Cauchy-Buniakovskii
inequality
for
integrals,
we obtain
2rr $- k
(1
(y -
Pylz
dt)“’ (p
d
(~ ,“;;t
t)2 dt)“’ <
0 dt ‘I* )
Analogously,
it
follows
that sin2 2t
(1 Choosing and (39),
c = 0.6,
(2%
1
and calculating
the
integrals
(1 + e cos t)? appearing
dt
‘/I )I
in
(30)
(29)
we obtain
For p = 1,
from
(31)
it
follows
mas o d{uxT+
that (V -
V,)2 < 0.683
(32)
1704
I.D.
Let into
us map the
the
rectangle
W plane,
lb11
by means of
Kill’
3.5,
<
lb,1
formulas the
domain
curve
0.5,
<
(26),
for
(see
c,, (l),
of the bl, bp plane, CI = 1. Then we obtain
Figure),
bounded
by the
where
mirl IQ (11,01 > 0.780 From (32) and (33) equality (27) holds. If
we map the
cry plane,
again
we obtain
the
is
bounded
follows
that
same rectangle using
domain
by the
From the
it
(X,
(26)
Figure
it
Figure)
cc is
the
but with
(see
curve
into
in-
~1 = 0,
which
(0).
readily
seen
that
min [CO(I), 0,] < miri [co [O), 0] uO, V0 are
The quantities the
following
inequality
linear
functions
of
~1; hence,
for
(34) 0 <:cl%l,
holds: (35)
min [cO (I), 01 < min IQ (p), 01 On the
other
hand,
the
quantity
(31)
is
an increasing
function
(32)
is
also
true
for
all
that
(27)
holds
easily the
hence
equation
The mapping carried
out
(2) of
(27)
the
the
CI
and thus
11.From
b,,
b,
side
satisfying
of
inequality
this
and 0 < CI< 1. For these
has solutions
boundary
on the right-hand
0<
interval
e = 0.6
has periodic
by means of
~1 for
p in the for
system
parameters,
appearing
of
it
follows
values (15),
of and
solutions. of
the
computing
rectangle
into
machine
“Strela”.
the
UV plane
was
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