Package gaiasky.util.gaia.utils
Class Interpolator
java.lang.Object
gaiasky.util.gaia.utils.Interpolator
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Nested Class Summary
Modifier and TypeClassDescriptionstatic class
Kind of interpolation: for derivative, value or integral -
Field Summary
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Constructor Summary
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Method Summary
Modifier and TypeMethodDescriptionstatic int
findLeftIndex(long[] xa, int xaLength, long x)
Deprecated.Mantis 14225, deprecated August 2, 2012.static int
getLeft(double ta, double[] t, int indx)
Find left such that t[left] <= ta < t[left+1]static int
getLeftVar(double ta, double[] t, int indx)
Find left such that t[left] <= ta < t[left+1] (but one less if ta == t[left+1])static double[]
hermite3(double x, double x0, double y0, double yp0, double x1, double y1, double yp1)
Static method for cubic Hermite interpolation between two points, given their values and derivatives.protected static double[]
interPolDer(double x)
For normalized argument x (between 0 and 1), calculate the derivatives ap0(x), ap1(x), bp0(x), bp1(x) of the four interpolating polynomialsprotected static double[]
interPolInt(double x)
For normalized argument x (between 0 and 1), calculate the integrals A0(x), A1(x), B0(x), B1(x) of the interpolating polynomials A0(x) = int_0^x a0(y)*dy (etc)protected static double[]
interPolVal(double x)
For normalized argument x (between 0 and 1), calculate the four interpolating polynomials a0(x), a1(x), b0(x), b1(x) [DRO-012, Eq.static double[]
linear(double x, double x0, double y0, double x1, double y1)
static Quaterniond
qEval(double tx, double[] t, Quaterniond[] q, Quaterniond[] qDot, int left, Interpolator.Kind kind)
Evaluates the quaternion derivative, value or integral at point tx, using Hermite interpolation in t[], q[], qDot[].static Quaterniond[]
qHermiteAverage(double ta, double tb, double[] t, int indx, Quaterniond[] q, Quaterniond[] qDot)
Static method for computing the average attitude quaternion over a finite time interval ta <= t <= tb, using cubic Hermite interpolation, as well as the average time derivative It is assumed that ta <= tb.
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Field Details
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dtMin
protected static double dtMin
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Constructor Details
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Interpolator
public Interpolator()
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Method Details
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hermite3
public static double[] hermite3(double x, double x0, double y0, double yp0, double x1, double y1, double yp1)Static method for cubic Hermite interpolation between two points, given their values and derivatives.- Parameters:
x
- desired abscissa (normally between x0 and x1)x0
- abscissa of first pointy0
- function value at x0yp0
- first derivative at x0x1
- abscissa of second pointy1
- function value at x1yp1
- derivative at x1- Returns:
- array with interpolated function value at x and its derivative
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linear
public static double[] linear(double x, double x0, double y0, double x1, double y1) -
qHermiteAverage
public static Quaterniond[] qHermiteAverage(double ta, double tb, double[] t, int indx, Quaterniond[] q, Quaterniond[] qDot)Static method for computing the average attitude quaternion over a finite time interval ta <= t <= tb, using cubic Hermite interpolation, as well as the average time derivative It is assumed that ta <= tb. If tb-ta is less than dtMin then no average is computed but the instantaneous (interpolated) values at the instant (ta+tb)/2 are returned instead. The times ta, tb, t[] are in [days] from some arbitrary but common origin. Time derivatives are in [1/day]. The lengths of the array arguments must be: t.length >= 2, q.length >= t.length, qDot-length >= t.length. No check is made of these conditions. The argument indx is such that t[indx] is not far from ta and tb. It must be in the range 0 <= indx <= t.length-2- Parameters:
ta
- start time of the averaging intervaltb
- end time of the averaging intervalt
- array array of increasing times encompassing the averaging interval (i.e., t[0] <= ta and tb <= t[t.length-1])indx
- an index in the array t[] that is a suitable starting point for locating ta and tb in the arrayq
- array of attitude quaternions at times t[]qDot
- array of attitude quaternion rates [1/timeUnit] at times t[]- Returns:
- array containing the average attitude quaternion as the first element and the average attitude quaternion rate [1/timeUnit] as the second element
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qEval
public static Quaterniond qEval(double tx, double[] t, Quaterniond[] q, Quaterniond[] qDot, int left, Interpolator.Kind kind)Evaluates the quaternion derivative, value or integral at point tx, using Hermite interpolation in t[], q[], qDot[]. left is such that t[left] <= tx < t[left+1]. Kind = DER returns the derivative at tx, VAL returns the value at tx, and INT returns the integral from t[left] to tx.- Parameters:
tx
- time at which the derivative, value or integral is evaluatedt
- array of times (length >= 2)q
- array of quaternionsqDot
- array of quaternion derivativesleft
- index in t, q and qDot susch that t[left] <= tx < t[left+1]kind
- which kind of result is returned (derivative, value or integral)- Returns:
- The quaternion
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getLeft
public static int getLeft(double ta, double[] t, int indx)Find left such that t[left] <= ta < t[left+1]- Parameters:
ta
-t
-indx
- starting index- Returns:
- The left index
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getLeftVar
public static int getLeftVar(double ta, double[] t, int indx)Find left such that t[left] <= ta < t[left+1] (but one less if ta == t[left+1])- Parameters:
ta
-t
-indx
- starting index- Returns:
- The left index
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interPolVal
protected static double[] interPolVal(double x)For normalized argument x (between 0 and 1), calculate the four interpolating polynomials a0(x), a1(x), b0(x), b1(x) [DRO-012, Eq. (8)]- Parameters:
x
-- Returns:
- double array containing a0, a1, b0, b1 at x
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interPolDer
protected static double[] interPolDer(double x)For normalized argument x (between 0 and 1), calculate the derivatives ap0(x), ap1(x), bp0(x), bp1(x) of the four interpolating polynomials- Parameters:
x
- The value- Returns:
- double array containing ap0, ap1, bp0, bp1 at x
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interPolInt
protected static double[] interPolInt(double x)For normalized argument x (between 0 and 1), calculate the integrals A0(x), A1(x), B0(x), B1(x) of the interpolating polynomials A0(x) = int_0^x a0(y)*dy (etc)- Parameters:
x
- The value- Returns:
- double array containing A0, A1, B0, B1 at x
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findLeftIndex
Deprecated.Mantis 14225, deprecated August 2, 2012. UseAttitudeUtils.findLeftIndex(long, long[], int)
. Remove by GT 18.0.In the non-decreasing sequence xa[0:n-1], finds the left index such that xa[left] <= x < xa[left+1] If x < xa[0] the method returns -1 if x >= xa[n-1], the last index to the array (n-1) is returned Uses a straight bisection method to locate the left index.- Parameters:
xa
- - array of non-decreasing valuesxaLength
- - ???x
- - value to locate- Returns:
- left index
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