Parameter of the Veverka photometric function. Usually : C_VEVERKA=1-A_VEVERKA
his parameter gives the absolut lower limit of the parameter of the Veverka photometric function. If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives the absolut upper limit of the parameter of the Veverka photometric function. If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives temperatur for the parameter of the Veverka photometric function.
This parameter gives the range over which random guesses can be expected to
vary at first:
A_VEVERKA_NEW = T_A_VEVERKA * tan( PI * ran_num + PI/2 ).
As the system cools the range will constrict gradually :
T_A_VEVERKA_NEW_* = T_A_VEVERKA_OLD_* * scale,
scale depends of NUMTEN.
Parameter of the Veverka photometric function.
his parameter gives the absolut lower limit of the parameter of the Veverka photometric function. If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives the absolut upper limit of the parameter of the Veverka photometric function. If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives temperatur for the parameter of the Veverka photometric function.
This parameter gives the range over which random guesses can be expected to
vary at first:
B_VEVERKA_NEW = T_B_VEVERKA * tan( PI * ran_num + PI/2 ).
As the system cools the range will constrict gradually :
T_B_VEVERKA_NEW_* = T_B_VEVERKA_OLD_* * scale,
scale depends of NUMTEN.
Parameter of the Veverka photometric function. Usually : C_VEVERKA=1-A_VEVERKA
his parameter gives the absolut lower limit of the parameter of the Veverka photometric function. If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives the absolut upper limit of the parameter of the Veverka photometric function. If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives temperatur for the parameter of the Veverka photometric function.
This parameter gives the range over which random guesses can be expected to
vary at first:
C_VEVERKA_NEW = T_C_VEVERKA * tan( PI * ran_num + PI/2 ).
As the system cools the range will constrict gradually :
T_C_VEVERKA_NEW_* = T_C_VEVERKA_OLD_* * scale,
scale depends of NUMTEN.
Parameter of the Veverka photometric function.
This parameter gives the absolut lower limit of the parameter of the Veverka photometric function. If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives the absolut upper limit of the parameter of the Veverka photometric function. If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives temperatur for the parameter of the Veverka photometric function.
This parameter gives the range over which random guesses can be expected to
vary at first:
D_VEVERKA_NEW = T_D_VEVERKA * tan( PI * ran_num + PI/2 ).
As the system cools the range will constrict gradually :
T_D_VEVERKA_NEW_* = T_D_VEVERKA_OLD_* * scale,
scale depends of NUMTEN.
Modification of the coefficient k in the Minnaert part of Mosher's photometric function (goes along with MO_EXP2).
This parameter gives the absolut lower limit of the modification of the coefficient k in the Minnaert part of Mosher's photometric function (goes along with MO_EXP2). If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives the absolut upper limit of the modification of the coefficient k in the Minnaert part of Mosher's photometric function (goes along with MO_EXP2). If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives temperatur for the modification of the coefficient k in
the Minnaert part of Mosher's photometric function (goes along with MO_EXP2).
This parameter gives the range over which random guesses can be expected to
vary at first:
MO_EXP1_NEW = T_MO_EXP1 * tan( PI * ran_num + PI/2 ).
As the system cools the range will constrict gradually :
T_MO_EXP1_NEW_* = T_MO_EXP1_OLD_* * scale,
scale depends of NUMTEN.
Modification of the coefficient k in the Minnaert part of Mosher's photometric function (goes along with MO_EXP1).
This parameter gives the absolut lower limit of the modification of the coefficient k in the Minnaert part of Mosher's photometric function (goes along with MO_EXP1). If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives the absolut upper limit of the modification of the coefficient k in the Minnaert part of Mosher's photometric function (goes along with MO_EXP1). If a sulution guess falls out-of-bonds then the attemp will be aborted and a new guess attempted.
This parameter gives temperatur for the modification of the coefficient k in
the Minnaert part of Mosher's photometric function (goes along with MO_EXP1).
This parameter gives the range over which random guesses can be expected to
vary at first:
MO_EXP2_NEW = T_MO_EXP2 * tan( PI * ran_num + PI/2 ).
As the system cools the range will constrict gradually :
T_MO_EXP2_NEW_* = T_MO_EXP2_OLD_* * scale,
scale depends of NUMTEN.