<HEAD><TITLE>DF01MD - SLICOT Library Routine Documentation</TITLE>

<H2><A Name="DF01MD">DF01MD</A></H2>

Sine transform or cosine transform of a real signal

<A HREF ="#Specification"><B>[Specification]</B></A>

<A HREF ="#Arguments"><B>[Arguments]</B></A>

<A HREF ="#Method"><B>[Method]</B></A>

<A HREF ="#References"><B>[References]</B></A>

<A HREF ="#Comments"><B>[Comments]</B></A>

<A HREF ="#Example"><B>[Example]</B></A>

<B><FONT SIZE="+1">Purpose</FONT></B>

To compute the sine transform or cosine transform of a real

signal.

<A name="Specification"><B><FONT SIZE="+1">Specification</FONT></B></A>

SUBROUTINE DF01MD( SICO, N, DT, A, DWORK, INFO )

C .. Scalar Arguments ..

CHARACTER SICO

INTEGER INFO, N

DOUBLE PRECISION DT

C .. Array Arguments ..

DOUBLE PRECISION A(*), DWORK(*)

<A name="Arguments"><B><FONT SIZE="+1">Arguments</FONT></B></A>

<B>Mode Parameters</B>

SICO CHARACTER*1

Indicates whether the sine transform or cosine transform

is to be computed as follows:

= 'S': The sine transform is computed;

= 'C': The cosine transform is computed.

<B>Input/Output Parameters</B>

N (input) INTEGER

The number of samples. N must be a power of 2 plus 1.

N &gt;= 5.

DT (input) DOUBLE PRECISION

The sampling time of the signal.

A (input/output) DOUBLE PRECISION array, dimension (N)

On entry, this array must contain the signal to be

processed.

On exit, this array contains either the sine transform, if

SICO = 'S', or the cosine transform, if SICO = 'C', of the

given signal.

<B>Workspace</B>

DWORK DOUBLE PRECISION array, dimension (N+1)

<B>Error Indicator</B>

INFO INTEGER

= 0: successful exit;

&lt; 0: if INFO = -i, the i-th argument had an illegal

value.

<A name="Method"><B><FONT SIZE="+1">Method</FONT></B></A>

Let A(1), A(2),..., A(N) be a real signal of N samples.

If SICO = 'S', the routine computes the sine transform of A as

follows. First, transform A(i), i = 1,2,...,N, into the complex

signal B(i), i = 1,2,...,(N+1)/2, where

B(1) = -2*A(2),

B(i) = {A(2i-2) - A(2i)} - j*A(2i-1) for i = 2,3,...,(N-1)/2,

B((N+1)/2) = 2*A(N-1) and j**2 = -1.

Next, perform a discrete inverse Fourier transform on B(i) by

calling SLICOT Library Routine DG01ND, to give the complex signal

Z(i), i = 1,2,...,(N-1)/2, from which the real signal C(i) may be

obtained as follows:

C(2i-1) = Re(Z(i)), C(2i) = Im(Z(i)) for i = 1,2,...,(N-1)/2.

Finally, compute the sine transform coefficients S ,S ,...,S

1 2 N

given by

S = 0,

1

{ [C(k) + C(N+1-k)] }

S = DT*{[C(k) - C(N+1-k)] - -----------------------},

k { [2*sin(pi*(k-1)/(N-1))]}

for k = 2,3,...,N-1, and

S = 0.

N

If SICO = 'C', the routine computes the cosine transform of A as

follows. First, transform A(i), i = 1,2,...,N, into the complex

signal B(i), i = 1,2,...,(N+1)/2, where

B(1) = 2*A(1),

B(i) = 2*A(2i-1) + 2*j*{[A(2i-2) - A(2i)]}

for i = 2,3,...,(N-1)/2 and B((N+1)/2) = 2*A(N).

Next, perform a discrete inverse Fourier transform on B(i) by

calling SLICOT Library Routine DG01ND, to give the complex signal

Z(i), i = 1,2,...,(N-1)/2, from which the real signal D(i) may be

obtained as follows:

D(2i-1) = Re(Z(i)), D(2i) = Im(Z(i)) for i = 1,2,...,(N-1)/2.

Finally, compute the cosine transform coefficients S ,S ,...,S

1 2 N

given by

S = 2*DT*[D(1) + A0],

1

{ [D(k) - D(N+1-k)] }

S = DT*{[D(k) + D(N+1-k)] - -----------------------},

k { [2*sin(pi*(k-1)/(N-1))]}

for k = 2,3,...,N-1, and

S = 2*DT*[D(1) - A0],

N

(N-1)/2

where A0 = 2*SUM A(2i).

i=1

<A name="References"><B><FONT SIZE="+1">References</FONT></B></A>

[1] Rabiner, L.R. and Rader, C.M.

Digital Signal Processing.

IEEE Press, 1972.

[2] Oppenheim, A.V. and Schafer, R.W.

Discrete-Time Signal Processing.

Prentice-Hall Signal Processing Series, 1989.

<A name="Numerical Aspects"><B><FONT SIZE="+1">Numerical Aspects</FONT></B></A>

The algorithm requires 0( N*log(N) ) operations.

<A name="Comments"><B><FONT SIZE="+1">Further Comments</FONT></B></A>

None

<A name="Example"><B><FONT SIZE="+1">Example</FONT></B></A>

<B>Program Text</B>

* DF01MD EXAMPLE PROGRAM TEXT

*

* .. Parameters ..

INTEGER NIN, NOUT

PARAMETER ( NIN = 5, NOUT = 6 )

INTEGER NMAX

PARAMETER ( NMAX = 129 )

* .. Local Scalars ..

DOUBLE PRECISION DT

INTEGER I, INFO, N

CHARACTER*1 SICO

* .. Local Arrays ..

DOUBLE PRECISION A(NMAX), DWORK(NMAX+1)

* .. External Functions ..

LOGICAL LSAME

EXTERNAL LSAME

* .. External Subroutines ..

EXTERNAL DF01MD

* .. Executable Statements ..

*

WRITE ( NOUT, FMT = 99999 )

* Skip the heading in the data file and read the data.

READ ( NIN, FMT = '()' )

READ ( NIN, FMT = * ) N, DT, SICO

IF ( N.LE.1 .OR. N.GT.NMAX ) THEN

WRITE ( NOUT, FMT = 99994 ) N

ELSE

READ ( NIN, FMT = * ) ( A(I), I = 1,N )

* Compute the sine/cosine transform of the given real signal.

CALL DF01MD( SICO, N, DT, A, DWORK, INFO )

*

IF ( INFO.NE.0 ) THEN

WRITE ( NOUT, FMT = 99998 ) INFO

ELSE

IF ( LSAME( SICO, 'S' ) ) THEN

WRITE ( NOUT, FMT = 99997 )

DO 20 I = 1, N

WRITE ( NOUT, FMT = 99995 ) I, A(I)

20 CONTINUE

ELSE

WRITE ( NOUT, FMT = 99996 )

DO 40 I = 1, N

WRITE ( NOUT, FMT = 99995 ) I, A(I)

40 CONTINUE

END IF

END IF

END IF

*

STOP

*

99999 FORMAT (' DF01MD EXAMPLE PROGRAM RESULTS',/1X)

99998 FORMAT (' INFO on exit from DF01MD = ',I2)

99997 FORMAT (' Components of sine transform are',//' i',6X,'A(i)',/)

99996 FORMAT (' Components of cosine transform are',//' i',6X,'A(i)',

$ /)

99995 FORMAT (I4,3X,F8.4)

99994 FORMAT (/' N is out of range.',/' N = ',I5)

END

<B>Program Data</B>

DF01MD EXAMPLE PROGRAM DATA

17 1.0 C

-0.1862

0.1288

0.3948

0.0671

0.6788

-0.2417

0.1861

0.8875

0.7254

0.9380

0.5815

-0.2682

0.4904

0.9312

-0.9599

-0.3116

0.8743

<B>Program Results</B>

DF01MD EXAMPLE PROGRAM RESULTS

Components of cosine transform are

i A(i)

1 28.0536

2 3.3726

3 -20.8158

4 6.0566

5 5.7317

6 -3.9347

7 -12.8074

8 -6.8780

9 16.2892

10 -17.0788

11 21.7836

12 -20.8203

13 -7.3277

14 -2.5325

15 -0.3636

16 7.8792

17 11.0048

<A HREF=..\libindex.html><B>Return to index</B></A></BODY>