Tags: Walter Gautschi Archives

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  1. 32-digit values of the first 100 recurrence coefficients for symmetric subrange Jacobi polynomials

    2016-11-02 17:45:54 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7R20ZB7

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=(1-x)^a*(1+x)^b on [-c,c], c=1/2, a=-1/2, b=1/2

    https://purr.purdue.edu/publications/2251

  2. 32-digit values of the first 100 recurrence coefficients for upper subrange Jacobi polynomials

    2016-11-02 15:58:36 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7VT1Q2N

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=(1-x)^a*(1+x)^b on [c,1], c=0, a=-1/2, b=1/2

    https://purr.purdue.edu/publications/2255

  3. 32-digit values of the first 100 recurrence coefficients for the 10th-order cardinal B-spline weight function

    2016-11-02 14:14:14 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R70K26JX

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=phi_m(x) on [0,m], m=10

    https://purr.purdue.edu/publications/2250

  4. 32-digit values of the first 100 recurrence coefficients for the second-order cardinal B-spline weight function obtained by discretization

    2016-11-02 14:11:43 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R74B2Z9Q

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=phi_m(x) on [0,m], m=2

    https://purr.purdue.edu/publications/2249

  5. OPCBSPL: Orthogonal polynomials relative to cardinal B-spline weight functions

    2016-10-28 13:32:02 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7NG4NKC

    A stable and efficient discretization procedure is developed to compute recurrence coefficients for orthogonal polynomials whose weight function is a polynomial cardinal B-spline of order greater than, or equal to, one.

    https://purr.purdue.edu/publications/2025

  6. 32-digit values of the first 100 recurrence coefficients for the weight function w(x)=[(1-x^2/2)*(1-x^2)]^(-1/2) on [-1,1]

    2016-10-28 13:05:57 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7HH6H1D

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=((1-om2*x^2)*(1-x^2))^(-1/2) on [-1,1], om2=1/2

    https://purr.purdue.edu/publications/2248

  7. 32-digit values of the first 100 recurrence coefficients for the reciprocal gamma weight function

    2016-10-27 13:48:35 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7S180GF

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=1/gamma(x) on [0,Inf]

    https://purr.purdue.edu/publications/2246

  8. 32-digit values of the first 100 recurrence coefficients for the finite-range exponential integral weight function on [0,1]

    2016-10-26 14:03:22 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R79021RG

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=E_nu(x) on (0,c], nu=1, c=1

    https://purr.purdue.edu/publications/2242

  9. 32-digit values of the first 100 recurrence coefficients for the exponential integral weight function E_1 on [0,Inf]

    2016-10-26 13:55:15 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7DR2SF2

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=E_nu(x) on (0,Inf], nu=1

    https://purr.purdue.edu/publications/2241

  10. 32-digit values of the first 100 recurrence coefficients for the finite-range exponential integral weight function on [0,16]

    2016-10-25 18:11:01 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7WS8R7X

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=E_nu(x) on (0,c], nu=1, c=16

    https://purr.purdue.edu/publications/2244

  11. 32-digit values of the first 100 recurrence coefficients for the coerror weight function

    2016-10-25 17:52:36 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R71J97Q6

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=erfc(x) on [0,Inf]

    https://purr.purdue.edu/publications/2245

  12. 32-digit values of the first 100 recurrence coefficients for the weight function w(x)=x^(1/2)*exp(-x)*(x-1-log(x)) on [0,Inf] obtained from moments

    2016-10-24 14:52:52 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7JH3J5S

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=x^a*exp(-x)*(x-1-log(x)) on [0,Inf], a=1/2

    https://purr.purdue.edu/publications/2240

  13. 32-digit values of the first 100 recurrence coefficients for the weight function w(x)=exp(-x)*(x-1-log(x)) on [0,Inf] obtained from moments

    2016-10-21 17:29:59 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7T151N8

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=x^a*exp(-x)*(x-1-log(x)) on [0,Inf], a=0

    https://purr.purdue.edu/publications/2238

  14. 32-digits values of the first 100 recurrence coefficients for the weight function w(x)=x^(1/2)*[log(1/x)]^2 on [0,1]

    2016-10-20 16:18:03 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7XS5SC9

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=x^a*[log(1/x)]^2 on [0,1], a=1/2

    https://purr.purdue.edu/publications/2237

  15. 32-digit values of the first 100 recurrence coefficients for the weight function w(x)=x^(-1/2)*[log(1/x)]^2 on [0,1]

    2016-10-20 16:06:04 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R72J68T4

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=x^a*[log(1/x)]^2 on [0,1], a=-1/2

    https://purr.purdue.edu/publications/2236

  16. 32-digit values of the first 100 recurrence coefficients for the Jacobi weight function on [0,1] with exponents 1/2 times a logarithmic factor

    2016-10-19 18:09:58 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R79Z92VJ

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=(1-x)^a*x^b*log(1/x) on [0,1], a=b=1/2

    https://purr.purdue.edu/publications/2234

  17. 32-digit values of the first 100 recurrence coefficients for the Jacobi weight function on [0,1] with exponents -1/2 times a logarithmic factor

    2016-10-19 16:03:00 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7FQ9TKW

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=(1-x)^a*x^b*log(1/x) on [0,1], a=b=-1/2

    https://purr.purdue.edu/publications/2233

  18. 32-digit values of the first 100 recurrence coefficients for the half-range generalized Hermite weight function with exponent 1/2

    2016-10-19 14:08:46 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7KH0K95

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=x^(2*mu)*exp(-x^2) on [0,Inf], mu=1/4

    https://purr.purdue.edu/publications/2232

  19. 32-digit values of the first 100 recurrence coefficients for the half-range generalized Hermite weight function with exponent -1/2

    2016-10-19 14:03:25 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7Q81B2B

    32-digit values of the first 100 recurrence coefficients for the weight function w(x)=x^(2*mu)*exp(-x^2) on [0,Inf], mu=-1/4

    https://purr.purdue.edu/publications/2231

  20. 32-digit values of the first 100 recurrence coefficients for an Airy weight function

    2016-10-19 13:50:30 | Datasets | Contributor(s): Walter Gautschi | doi:10.4231/R7V122R6

    32-digit values of the first 100 recurrence coefficients for the (normalized) weight function w(x)=c*x^(-5/6)e^(-x)Ai((3x/2)^(2/3)) on [0,Inf], c=2^(-1/6)*3^(1/6)/pi^(1/2), where Ai is the Airy function

    https://purr.purdue.edu/publications/2031

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