Document revision date: 19 July 1999
|
|
|
|
OpenVMS VAX RTL Mathematics (MTH$) Manual
MTH$xATAND
Given the tangent of an angle, the Arc Tangent in Degrees routine
returns that angle (in degrees).
Format
MTH$ATAND tangent
MTH$DATAND tangent
MTH$GATAND tangent
Each of the above formats accepts one of the floating-point types as
input. Corresponding JSB Entry Points
MTH$ATAND_R4
MTH$DATAND_R7
MTH$GATAND_R7
Each of the above JSB entry points accepts one of the floating-point
types as input.
RETURNS
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
write only |
mechanism: |
by value |
Angle in degrees. The angle returned will have a value in the range:
MTH$ATAND returns an F-floating number. MTH$DATAND returns a D-floating
number. MTH$GATAND returns a G-floating number.
Argument
tangent
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
read only |
mechanism: |
by reference |
The tangent of the angle whose value (in degrees) is to be returned.
The tangent argument is the address of a
floating-point number that is this tangent. For MTH$ATAND,
tangent specifies an F-floating number. For
MTH$DATAND, tangent specifies a D-floating number. For
MTH$GATAND, tangent specifies a G-floating number.
Description
The computation of the arc tangent function is based on the following
identities:
|
arctan(X) = (180/Pi sign)* (X - X
3/3 + X
5/5 - X
7/7 + ...)
|
|
arctan(X) = 64*X + X*Q(X
2),
where Q(Y) = 180/Pi*[(1- 64*Pi sign/180)] - Y/3 + Y
2/5 - Y
3/7 + Y
4/9
|
|
arctan(X) = X*P(X
2),
where P(Y) = 180/Pi sign*[1 - Y/3 + Y
2/5 - Y
3/7 + Y
4/9 ...]
|
|
arctan(X) = 90 - arctan(1/X)
|
|
arctan(X) = arctan(A) + arctan((X - A)/(1 + A*X))
|
The angle in degrees whose tangent is X is computed as:
Tangent |
Angle Returned |
X
<= 3/32
|
64*X + X*Q(X
2)
|
3/32
< X
<= 11
|
ATAND(A) + V*P(V
2) , where A and ATAND(A) are chosen by table lookup and V
=(X - A)/(1 + A*X)
|
11
< X
|
90 - W * (P(W
2)), where W = 1/X
|
X
< 0
|
-zATAND(|X|)
|
See MTH$HATAND for the description of the H-floating point version of
this routine.
Condition Value Signaled
SS$_ROPRAND
|
Reserved operand. The MTH$xATAND routine encountered a floating-point
reserved operand due to incorrect user input. A floating-point reserved
operand is a floating-point datum with a sign bit of 1 and a biased
exponent of 0. Floating-point reserved operands are reserved for future
use by Digital.
|
MTH$xATAN2
Given sine and cosine, the Arc
Tangent in Radians with Two Arguments routine returns the angle (in
radians) whose tangent is given by the quotient of
sine and cosine
(sine/cosine).
Format
MTH$ATAN2 sine ,cosine
MTH$DATAN2 sine ,cosine
MTH$GATAN2 sine ,cosine
Each of the above formats accepts one of the floating-point types as
input.
RETURNS
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
write only |
mechanism: |
by value |
Angle in radians. MTH$ATAN2 returns an F-floating number. MTH$DATAN2
returns a D-floating number. MTH$GATAN2 returns a G-floating number.
Arguments
sine
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
read only |
mechanism: |
by reference |
Dividend. The sine argument is the address of a
floating-point number that is this dividend. For MTH$ATAN2,
sine specifies an F-floating number. For MTH$DATAN2,
sine specifies a D-floating number. For MTH$GATAN2,
sine specifies a G-floating number.
cosine
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
read only |
mechanism: |
by reference |
Divisor. The cosine argument is the address of a
floating-point number that is this divisor. For MTH$ATAN2,
cosine specifies an F-floating number. For MTH$DATAN2,
cosine specifies a D-floating number. For MTH$GATAN2,
cosine specifies a G-floating number.
Description
The angle in radians whose tangent is Y/X is computed
as follows, where f is defined in the description of MTH$zCOSH.
Value of Input Arguments |
Angle Returned |
X = 0 or Y/X > 2
(f+1)
|
Pi sign/2* (sign Y)
|
X > 0 and Y/X
<= 2
(f+1)
|
zATAN(Y/X)
|
X
< 0 and Y/X
<= 2
(f+1)
|
Pi sign* (sign Y) + zATAN(Y/X)
|
See MTH$HATAN2 for the description of the H-floating point version of
this routine.
Condition Values Signaled
SS$_ROPRAND
|
Reserved operand. The MTH$xATAN2 routine encountered a floating-point
reserved operand due to incorrect user input. A floating-point reserved
operand is a floating-point datum with a sign bit of 1 and a biased
exponent of 0. Floating-point reserved operands are reserved for future
use by Digital.
|
MTH$_INVARGMAT
|
Invalid argument. Both
cosine and
sine are zero. LIB$SIGNAL copies the floating-point
reserved operand to the mechanism argument vector CHF$L_MCH_SAVR0/R1.
The result is the floating-point reserved operand unless you have
written a condition handler to change CHF$L_MCH_SAVR0/R1.
|
MTH$xATAND2
Given sine and cosine, the Arc
Tangent in Degrees with Two Arguments routine returns the angle (in
degrees) whose tangent is given by the quotient of
sine and cosine
(sine/cosine).
Format
MTH$ATAND2 sine ,cosine
MTH$DATAND2 sine ,cosine
MTH$GATAND2 sine ,cosine
Each of the above formats accepts one of the floating-point types as
input.
RETURNS
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
write only |
mechanism: |
by value |
Angle in degrees. MTH$ATAND2 returns an F-floating number. MTH$DATAND2
returns a D-floating number. MTH$GATAND2 returns a G-floating number.
Arguments
sine
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
read only |
mechanism: |
by reference |
Dividend. The sine argument is the address of a
floating-point number that is this dividend. For MTH$ATAND2,
sine specifies an F-floating number. For MTH$DATAND2,
sine specifies a D-floating number. For MTH$GATAND2,
sine specifies a G-floating number.
cosine
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
read only |
mechanism: |
by reference |
Divisor. The cosine argument is the address of a
floating-point number that is this divisor. For MTH$ATAND2,
cosine specifies an F-floating number. For
MTH$DATAND2, cosine specifies a D-floating number. For
MTH$GATAND2, cosine specifies a G-floating number.
Description
The angle in degrees whose tangent is Y/X is computed
below and where f is defined in the description of MTH$zCOSH.
Value of Input Arguments |
Angle Returned |
X = 0 or Y/X > 2
(f+1)
|
90* (sign Y)
|
X > 0 and Y/X
<= 2
(f+1)
|
zATAND(Y/X)
|
X
< 0 and Y/X
<= 2
(f+1)
|
180 * (sign Y) + zATAND(Y/X)
|
See MTH$HATAND2 for the description of the H-floating point version of
this routine.
Condition Values Signaled
SS$_ROPRAND
|
Reserved operand. The MTH$xATAND2 routine encountered a floating-point
reserved operand due to incorrect user input. A floating-point reserved
operand is a floating-point datum with a sign bit of 1 and a biased
exponent of 0. Floating-point reserved operands are reserved for future
use by Digital.
|
MTH$_INVARGMAT
|
Invalid argument. Both
cosine and
sine are zero. LIB$SIGNAL copies the floating-point
reserved operand to the mechanism argument vector CHF$L_MCH_SAVR0/R1.
The result is the floating-point reserved operand unless you have
written a condition handler to change CHF$L_MCH_SAVR0/R1.
|
MTH$xATANH
Given the hyperbolic tangent of an angle, the Hyperbolic Arc Tangent
routine returns the hyperbolic arc tangent of that angle.
Format
MTH$ATANH hyperbolic-tangent
MTH$DATANH hyperbolic-tangent
MTH$GATANH hyperbolic-tangent
Each of the above formats accepts one of the floating-point types as
input.
RETURNS
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
write only |
mechanism: |
by value |
The hyperbolic arc tangent of hyperbolic-tangent.
MTH$ATANH returns an F-floating number. MTH$DATANH returns a D-floating
number. MTH$GATANH returns a G-floating number.
Argument
hyperbolic-tangent
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
read only |
mechanism: |
by reference |
Hyperbolic tangent of an angle. The hyperbolic-tangent
argument is the address of a floating-point number that is this
hyperbolic tangent. For MTH$ATANH, hyperbolic-tangent
specifies an F-floating number. For MTH$DATANH,
hyperbolic-tangent specifies a D-floating number. For
MTH$GATANH, hyperbolic-tangent specifies a G-floating
number.
Description
The hyperbolic arc tangent function is computed as follows:
Value of x |
Value Returned |
|X|
< 1
|
zATANH(X) = zLOG((1+X)/(1-X))/2
|
|X| => 1
|
An invalid argument is signaled
|
See MTH$HATANH for the description of the H-floating point version of
this routine.
Condition Values Signaled
SS$_ROPRAND
|
Reserved operand. The MTH$xATANH routine encountered a floating-point
reserved operand due to incorrect user input. A floating-point reserved
operand is a floating-point datum with a sign bit of 1 and a biased
exponent of 0. Floating-point reserved operands are reserved for future
use by Digital.
|
MTH$_INVARGMAT
|
Invalid argument: |X| => 1 . LIB$SIGNAL copies the floating-point
reserved operand to the mechanism argument vector CHF$L_MCH_SAVR0/R1.
The result is the floating-point reserved operand unless you have
written a condition handler to change CHF$L_MCH_SAVR0/R1.
|
MTH$CxABS
The Complex Absolute Value routine returns the absolute value of a
complex number (r,i).
Format
MTH$CABS complex-number
MTH$CDABS complex-number
MTH$CGABS complex-number
Each of the above formats accepts one of the floating-point complex
types as input.
RETURNS
OpenVMS usage: |
floating_point |
type: |
F_floating, D_floating, G_floating |
access: |
write only |
mechanism: |
by value |
The absolute value of a complex number. MTH$CABS returns an F-floating
number. MTH$CDABS returns a D-floating number. MTH$CGABS returns a
G-floating number.
Argument
complex-number
OpenVMS usage: |
complex_number |
type: |
F_floating complex, D_floating complex, G_floating
complex |
access: |
read only |
mechanism: |
by reference |
A complex number (r,i), where r and i are both floating-point complex
values. The complex-number argument is the address of
this complex number. For MTH$CABS, complex-number
specifies an F-floating complex number. For MTH$CDABS,
complex-number specifies a D-floating complex number.
For MTH$CGABS, complex-number specifies a G-floating
complex number.
Description
The complex absolute value is computed as follows, where MAX
is the larger of |r| and |i|, and MIN is the smaller of |r|
and |i|:
result = MAX * SQRT((MIN/MAX)2 + 1)
Condition Values Signaled
SS$_ROPRAND
|
Reserved operand. The MTH$CxABS routine encountered a floating-point
reserved operand due to incorrect user input. A floating-point reserved
operand is a floating-point datum with a sign bit of 1 and a biased
exponent of 0. Floating-point reserved operands are reserved for future
use by Digital.
|
MTH$_FLOOVEMAT
|
Floating-point overflow in Math Library when both
r and
i are large.
|
Examples
#1 |
C+
C This Fortran example forms the absolute value of an
C F-floating complex number using MTH$CABS and the
C Fortran random number generator RAN.
C
C Declare Z as a complex value and MTH$CABS as a REAL*4 value.
C MTH$CABS will return the absolute value of Z: Z_NEW = MTH$CABS(Z).
C-
COMPLEX Z
COMPLEX CMPLX
REAL*4 Z_NEW,MTH$CABS
INTEGER M
M = 1234567
C+
C Generate a random complex number with the Fortran generic CMPLX.
C-
Z = CMPLX(RAN(M),RAN(M))
C+
C Z is a complex number (r,i) with real part "r" and
C imaginary part "i".
C-
TYPE *, ' The complex number z is',z
TYPE *, ' It has real part',REAL(Z),'and imaginary part',AIMAG(Z)
TYPE *, ' '
C+
C Compute the complex absolute value of Z.
C-
Z_NEW = MTH$CABS(Z)
TYPE *, ' The complex absolute value of',z,' is',Z_NEW
END
|
This example uses an F-floating complex number for
complex-number. The output of this Fortran example is
as follows:
The complex number z is (0.8535407,0.2043402)
It has real part 0.8535407 and imaginary part 0.2043402
The complex absolute value of (0.8535407,0.2043402) is 0.8776597
|
#2 |
C+
C This Fortran example forms the absolute
C value of a G-floating complex number using
C MTH$CGABS and the Fortran random number
C generator RAN.
C
C Declare Z as a complex value and MTH$CGABS as a
C REAL*8 value. MTH$CGABS will return the absolute
C value of Z: Z_NEW = MTH$CGABS(Z).
C-
COMPLEX*16 Z
REAL*8 Z_NEW,MTH$CGABS
C+
C Generate a random complex number with the Fortran
C generic CMPLX.
C-
Z = (12.34567890123,45.536376385345)
TYPE *, ' The complex number z is',z
TYPE *, ' '
C+
C Compute the complex absolute value of Z.
C-
Z_NEW = MTH$CGABS(Z)
TYPE *, ' The complex absolute value of',z,' is',Z_NEW
END
|
This Fortran example uses a G-floating complex number for
complex-number. Because this example uses a G-floating
number, it must be compiled as follows:
Notice the difference in the precision of the output generated:
The complex number z is (12.3456789012300,45.5363763853450)
The complex absolute value of (12.3456789012300,45.5363763853450) is
47.1802645376230
|
MTH$CCOS
The Cosine of a Complex Number (F-Floating Value) routine returns the
cosine of a complex number as an F-floating value.
Format
MTH$CCOS complex-number
RETURNS
OpenVMS usage: |
complex_number |
type: |
F_floating complex |
access: |
write only |
mechanism: |
by value |
The complex cosine of the complex input number. MTH$CCOS returns an
F-floating complex number.
Argument
complex-number
OpenVMS usage: |
complex_number |
type: |
F_floating complex |
access: |
read only |
mechanism: |
by reference |
A complex number (r,i) where r and i are floating-point numbers. The
complex-number argument is the address of this complex
number. For MTH$CCOS, complex-number specifies an
F-floating complex number.
Description
The complex cosine is calculated as follows:
result = (COS(r) *
COSH(i), -SIN(r) * SINH(i))
See MTH$CxCOS for the descriptions of the D- and G-floating point
versions of this routine.
Condition Values Signaled
SS$_ROPRAND
|
Reserved operand. The MTH$CCOS routine encountered a floating-point
reserved operand due to incorrect user input. A floating-point reserved
operand is a floating-point datum with a sign bit of 1 and a biased
exponent of 0. Floating-point reserved operands are reserved for future
use by Digital.
|
MTH$_FLOOVEMAT
|
Floating-point overflow in Math Library: the absolute value of
i is greater than about 88.029 for F-floating values.
|
Example
|
C+
C This Fortran example forms the complex
C cosine of an F-floating complex number using
C MTH$CCOS and the Fortran random number
C generator RAN.
C
C Declare Z and MTH$CCOS as complex values.
C MTH$CCOS will return the cosine value of
C Z: Z_NEW = MTH$CCOS(Z)
C-
COMPLEX Z,Z_NEW,MTH$CCOS
COMPLEX CMPLX
INTEGER M
M = 1234567
C+
C Generate a random complex number with the
C Fortran generic CMPLX.
C-
Z = CMPLX(RAN(M),RAN(M))
C+
C Z is a complex number (r,i) with real part "r" and
C imaginary part "i".
C-
TYPE *, ' The complex number z is',z
TYPE *, ' It has real part',REAL(Z),'and imaginary part',AIMAG(Z)
TYPE *, ' '
C+
C Compute the complex cosine value of Z.
C-
Z_NEW = MTH$CCOS(Z)
TYPE *, ' The complex cosine value of',z,' is',Z_NEW
END
|
This Fortran example demonstrates the use of MTH$CCOS, using the
MTH$CCOS entry point. The output of this program is as follows:
The complex number z is (0.8535407,0.2043402)
It has real part 0.8535407 and imaginary part 0.2043402
The complex cosine value of (0.8535407,0.2043402) is (0.6710899,-0.1550672)
|