! #include "copyright.h" #include "../include/dprec.fh" !+++++++++++++++++++++++++++++++++++++++ !This module contains various parameters !and constants used by the different !routines that make up sander. ! !If you want to use one of the constants !in your routine you should include the !line: ! !use constants, only : xxx, yyy, zzz ! !where xxx,yyy,zzz are the constants you plan !to use in your routine. !This line needs to go before the !implicit none declaration. ! ! Based on constants.h, a pre Fortran 90 version, by Scott Brozell ! and Dave Case (TSRI, 2002) ! Converted into a Fortran 90 module by: Ross Walker (TSRI, 2005) ! Expanded by others including: Matthew Clark, Andreas Goetz, ! !++++++++++++++++++++++++++++++++++++++++ module constants implicit none ! by default everything in this module is public public !------------------------------------------------------------ ! Generic Floating Point Constants _REAL_, parameter :: TEN_TO_MINUS2 = 1.0d-2 _REAL_, parameter :: TEN_TO_MINUS3 = 1.0d-3 _REAL_, parameter :: TEN_TO_MINUS4 = 1.0d-4 _REAL_, parameter :: TEN_TO_MINUS5 = 1.0d-5 _REAL_, parameter :: TEN_TO_MINUS6 = 1.0d-6 _REAL_, parameter :: TEN_TO_MINUS8 = 1.0d-8 _REAL_, parameter :: TEN_TO_MINUS10 = 1.0d-10 _REAL_, parameter :: TEN_TO_MINUS25 = 1.0d-25 _REAL_, parameter :: TEN_TO_PLUS3 = 1.0d+3 _REAL_, parameter :: TEN_TO_PLUS10 = 1.0d+10 _REAL_, parameter :: zero = 0.0d0 _REAL_, parameter :: one = 1.0d0 _REAL_, parameter :: two = 2.0d0 _REAL_, parameter :: three = 3.0d0 _REAL_, parameter :: four = 4.0d0 _REAL_, parameter :: five = 5.0d0 _REAL_, parameter :: six = 6.0d0 _REAL_, parameter :: seven = 7.0d0 _REAL_, parameter :: eight = 8.0d0 _REAL_, parameter :: nine = 9.0d0 _REAL_, parameter :: ten = 10.0d0 _REAL_, parameter :: eleven = 11.0d0 _REAL_, parameter :: twelve = 12.0d0 _REAL_, parameter :: sixteen = 16.0d0 _REAL_, parameter :: twenty = 20.0d0 _REAL_, parameter :: thirtytwo = 32.0d0 _REAL_, parameter :: sixtyfour = 64.0d0 _REAL_, parameter :: half = one/two _REAL_, parameter :: third = one/three _REAL_, parameter :: fourth = one/four _REAL_, parameter :: fifth = one/five _REAL_, parameter :: sixth = one/six _REAL_, parameter :: seventh = one/seven _REAL_, parameter :: eighth = one/eight _REAL_, parameter :: ninth = one/nine _REAL_, parameter :: tenth = one/ten _REAL_, parameter :: eleventh = one/eleven _REAL_, parameter :: twelfth = one/twelve _REAL_, parameter :: sixteenth = one/sixteen _REAL_, parameter :: thirtysecond = one/thirtytwo _REAL_, parameter :: sixtyfourth = one/sixtyfour _REAL_, parameter :: thirtieth = one/30.0d0 !------------------------------------------------------------ ! THE ARRAY FC(I) CONTAINS THE FACTORIALS OF (I-1). _REAL_, parameter :: FC(1:17) =& (/ 1.0D0,1.0D0, 2.0D0, 6.0D0, 24.0D0, 120.0D0, 720.0D0, 5040.0D0, & 40320.0D0, 362880.0D0, 3628800.0D0, 39916800.0D0, & 4.790016D+08, 6.2270208D+09, 8.71782912D+10, & 1.307674368D+12, 2.092278989D+13 /) _REAL_, parameter :: logFC(1:17) = (/ 0.0D0, 0.0D0, 0.6931471805599D0, & & 1.7917594692281D0, 3.1780538303479D0, 4.7874917427820D0, & & 6.5792512120101D0, 8.5251613610654D0, 10.6046029027453D0, & & 12.8018274800815D0, 15.1044125730755D0, 17.5023078458739D0, & & 19.9872144956619D0, 22.5521638531234D0, 25.1912211827387D0, & & 27.8992713838409D0, 30.6718601061763D0 /) ! DEFINE C COEFFICIENTS FOR ASSOCIATE LEGENDRE POLYNOMIALS. _REAL_, parameter::CC(1:21,1:3) = reshape ( (/ & 8.0D0, 8.0D0, 4.0D0, -4.0D0, 4.0D0, & 4.0D0, -12.0D0, -6.0D0, 20.0D0, 5.0D0, & 3.0D0, -30.0D0, -10.0D0, 35.0D0, 7.0D0, & 15.0D0, 7.5D0, -70.0D0, -17.5D0, 63.0D0, & 10.5D0, & 0.0D0, 0.0D0, 0.0D0, 12.0D0, 0.0D0, & 0.0D0, 20.0D0, 30.0D0, 0.0D0, 0.0D0, & -30.0D0, 70.0D0, 70.0D0, 0.0D0, 0.0D0, & -70.0D0, -105.D0, 210.0D0, 157.5D0, 0.0D0, & 0.0D0, & 0.0D0, 0.0D0, 0.0D0, 0.0D0, 0.0D0, & 0.0D0, 0.0D0, 0.0D0, 0.0D0, 0.0D0, & 35.0D0, 0.0D0, 0.0D0, 0.0D0, 0.0D0, & 63.0D0, 157.5D0, 0.0D0, 0.0D0, 0.0D0, & 0.0D0/), (/ 21, 3 /) ) !------------------------------------------------------------ ! Physical Constants _REAL_, parameter :: LIGHT_SPEED = 2.997924d08 _REAL_, parameter :: HBAR = 627.509d0 * 0.0241888d-3 * 20.455d0 !Planck's constant in internal units _REAL_, parameter :: J_PER_CAL = 4.184d0 ! This is defined as the thermochemical calorie _REAL_, parameter :: JPKC = J_PER_CAL * 1000.0d0 !kilocalories per joule _REAL_, parameter :: BOLTZMANN = 1.380658d-23 !Boltzmann's constant in J/K _REAL_, parameter :: AVOGADRO = 6.0221367d+23 !Avogadro's number _REAL_, parameter :: KB = (BOLTZMANN * AVOGADRO) / JPKC !Boltzmann's constant in internal units _REAL_, parameter :: AMBER_ELECTROSTATIC = 18.2223d0 _REAL_, parameter :: AMBER_ELECTROSTATIC2 = AMBER_ELECTROSTATIC * AMBER_ELECTROSTATIC !Ratio by which to scale amber charges to get electron charges - amberchg * oneqscale = electron charges ! = 1.0 / 18.2223d0 _REAL_, parameter :: INV_AMBER_ELECTROSTATIC = 1.0d0/AMBER_ELECTROSTATIC _REAL_, parameter :: INV_AMBER_ELECTROSTATIC2 = 1.0d0/AMBER_ELECTROSTATIC2 _REAL_, parameter :: CHARGE_ON_ELEC = 1.60217733d-19 !Charge on an electron in Coulombs _REAL_, parameter :: BOHR_RADIUS = 52.9177249d-12 ! in meter _REAL_, parameter :: BOHRS_TO_A = 0.529177249D0 ! Bohrs * this = angstroms - Same constants as used in dynamo v2. !_REAL_, parameter :: BOHRS_TO_A = 0.52917706D0 ! Bohrs * this = angstroms - Same constants as used in Gaussian 98 !_REAL_, parameter :: BOHRS_TO_A = 0.529177D0 ! Bohrs * this = angstroms - Same constants as used in Mopac6 hcore.f !_REAL_, parameter :: BOHRS_TO_A = 0.529167D0 ! as used in Mopac6 repp.f _REAL_, parameter :: A_TO_BOHRS = 1.0d0 / BOHRS_TO_A !_REAL_, parameter :: A_TO_BOHRS = 1.88976D0 !Same constants as used in Mopac6 gover.f _REAL_, parameter :: A2_TO_BOHRS2 = A_TO_BOHRS * A_TO_BOHRS !Mopac6 uses 3.5711928576D0 in gover.f for this. _REAL_, parameter :: A3_TO_BOHRS3 = A2_TO_BOHRS2 * A_TO_BOHRS _REAL_, parameter :: A4_TO_BOHRS4 = A2_TO_BOHRS2 * A2_TO_BOHRS2 _REAL_, parameter :: ONE_AU = 27.2113962d0 !One atomic unit of energy in eV. _REAL_, parameter :: HARTREE_TO_JOULE = ONE_AU * CHARGE_ON_ELEC !conversion from hartrees to joules _REAL_, parameter :: HART_BOHR_TO_JOULE_A = HARTREE_TO_JOULE * BOHRS_TO_A !hartree*bohrs to joules*angstroms _REAL_, parameter :: COULOMB_CONST_E = HART_BOHR_TO_JOULE_A*AVOGADRO/JPKC !Coulomb's constant for charges in units of e !This is the same as AMBER_ELECTROSTATIC2 but to higher precision !_REAL_, parameter :: AU_TO_EV = ONE_AU !Conversion from AU to EV - not used because we match dynamo v2 below. _REAL_, parameter :: AU_TO_EV = 27.21d0 !Conversion from AU to EV - Same as dynamo v2 uses and Gaussian 98 !Note (RCW+MC): more precise would be: 1 a.u. 27.211396 eV !Mopac6 uses 27.21D0 in calpar.f, delri.f and repp.f but in !ffhpol.f it uses 27.2107 and in the manual it quotes 27.211 _REAL_, parameter :: HALF_AU_TO_EV = AU_TO_EV * half _REAL_, parameter :: FOURTH_AU_TO_EV = AU_TO_EV * fourth _REAL_, parameter :: EIGHTH_AU_TO_EV = AU_TO_EV * eighth _REAL_, parameter :: SXNTH_AU_TO_EV = EIGHTH_AU_TO_EV * half _REAL_, parameter :: A2_TO_BOHRS2xAU_TO_EV = A2_TO_BOHRS2*AU_TO_EV !_REAL_, parameter :: EV_TO_KCAL = 23.060362D0 !Conversion from EV to KCAL/MOL !Dynamo parameter _REAL_, parameter :: EV_TO_KCAL = 23.061d0 !Dynamo's conversion !Mopac6 uses 23.061 in ffhpol.f analyt.f compfg.f datin.f dcart.f ! delri1.f delri2.f deritr.f interp.f iter.f ! moldat.f mopac.f _REAL_, parameter :: KCAL_TO_EV = one / EV_TO_KCAL _REAL_, parameter :: AU_TO_KCAL = AU_TO_EV*EV_TO_KCAL !1 hartree. ! The following are updated constants from Mohr, Taylor, Newell, Rev. Mod. Phys. 80 (2008) 633-730. !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~! ! NAME REFERENCE VALUE UNITS ! !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~! ! Avogadro constant (Table XLVIII, p.708) 6.0221417930E23 mol^-1 ! ! Bohr radius (Table XLIX, p. 710) 0.5291772085936E-10 m ! ! a.u. of energy (Table LII, p. 717) 4.3597439422E-18 J ! ! speed of light (vacuum) (Table I, p.637) 299 792 458 m*s^−1 ! ! a.u. of charge (Table LIII, p. 717) 1.60217648740E-19 C ! !~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~! _REAL_, parameter :: CODATA08_AVOGADRO = 6.0221417930d23 ! Avogadro's number _REAL_, parameter :: CODATA08_BOHR_RADIUS = 0.5291772085936d-10 _REAL_, parameter :: CODATA08_ONE_AU = 4.3597439422d-18 ! Atomic unit of energy in joules _REAL_, parameter :: CODATA08_LIGHT_SPEED = 2.99792458d08 _REAL_, parameter :: CODATA08_CHARGE_ON_ELEC = 1.60217648740d-19 ! Derived values _REAL_, parameter :: CODATA08_A_TO_BOHRS = 1d-10 / CODATA08_BOHR_RADIUS _REAL_, parameter :: CODATA08_AU_TO_KCAL = CODATA08_ONE_AU / J_PER_CAL / 1000 * CODATA08_AVOGADRO _REAL_, parameter :: CODATA08_AU_TO_DEBYE = & CODATA08_LIGHT_SPEED * CODATA08_CHARGE_ON_ELEC * CODATA08_BOHR_RADIUS / 1d-21 !_REAL_, parameter :: AU_TO_DEBYE = 1.0d0/0.393430 ! from http://cccbdb.nist.gov/debye.asp (April 12 2011) !------------------------------------------------------------ !Numeric Constants _REAL_, parameter :: PI = 3.1415926535897932384626433832795d0 !The BOOK says : ! !2Chronicles 4:2 reads thus, 'Also he made a molten sea of ten cubits !from brim to brim, round in compass, and five cubits the height thereof; !and a line of thirty cubits did compass it round about.' ! !Hence, Pi is exactly equal to three and there is nothing more to discuss! ! !If you want to use the value of PI defined by 'the BOOK' then uncomment !the following line and comment out the definition above... !_REAL_, parameter :: PI = 3.0d0 _REAL_, parameter :: PI2 = PI*PI _REAL_, parameter :: HALFPI = PI * 0.5d0 _REAL_, parameter :: TWOPI = 2.0d0 * PI _REAL_, parameter :: FOURPI = 4.0d0 * PI _REAL_, parameter :: INVPI = 1.0d0 / PI _REAL_, parameter :: SQRTPI = 1.77245385090551602729816748334d0 !sqrt(PI) _REAL_, parameter :: INVSQRTPI = 1.0d0 / SQRTPI _REAL_, parameter :: DEG_TO_RAD = PI / 180.0d0 _REAL_, parameter :: RAD_TO_DEG = 180.0d0 / PI _REAL_, parameter :: LN_TO_LOG = 2.30258509299404568402d0 ! log(1.0d1) _REAL_, parameter :: SQRT2 = 1.4142135623730950488016887242097d0 _REAL_, parameter :: INVSQRT2 = 1.0d0 / SQRT2 !------------------------------------------------------------ !Generalised Born Constants _REAL_, parameter :: alpb_alpha = 0.571412d0 !Alpha prefactor for alpb_alpha !------------------------------------------------------------ ! Unusual Constants integer, parameter :: RETIRED_INPUT_OPTION = -10301 ! first 5 digit palindromic prime integer, parameter :: NO_INPUT_VALUE = 12344321 ! from Bob Duke _REAL_, parameter :: NO_INPUT_VALUE_FLOAT = 12344321.d0 contains function BinomialCoefficient(m, n) result (bioCoeff) integer, intent(in)::m,n _REAL_::bioCoeff integer, parameter::size=30 integer, save::bc(size,size)=0 logical, save::initialized=.false.; integer::i,j,k if (.not.initialized) then do i=1,size bc(i,1)=one bc(i,2:size)=zero end do do i=2, size do j=2, i bc(i,j)=bc(i-1,j-1)+bc(i-1,j) end do end do initialized=.true. end if bioCoeff=one*bc(m,n) end function BinomialCoefficient end module constants