Do you have any experience with recursive algorithms? (I bet you do.)

I'm new to coding (1 week of every now and again coding) and I've been working on something (explanation below). I want to code an "application" that will plot the n'th reagent's concentration in time function of a chain reaction: A->B->C->D->...

The thing is, c_n(t) contains 2^n - 1 exponential functions - which are nested based on a pattern I've found:

```
c_1(t) = c_0_1 * exp(-k_1 * t)
c_2(t) = c_0_2 * exp(-k_2 * t) + c_0_1 * k_1 * {[exp(-k_1 * t) - exp(-k_2 * t)]/[k_2 - k_1]}
c_3(t) = c_0_3 * exp(-k_3 * t) + c_0_2 * k_2 * {[exp(-k_2 * t) - exp(-k_3 * t)]/[k_3 - k_2]} + c_0_1 * k_1 * k_2 * [1/(k_2-k_1)] * <{[exp(-k_1 * t) - exp(-k_3 * t)]/[k_3 - k_1]} - {[exp(-k_2 * t) - exp(-k_3 * t)]/[k_3 - k_2]}>
```

As you can see, each equation is a sum of reappearing elements. The number of nestings is dependent on the degree of relationship: 0-th degree (A to A) - simple exponential function, 1st degree (A to B, B to C, etc.) - 1 nesting, 2nd degree (A to C, B to D, etc.) - 2 nestings, etc.

Each equation can be divided into reappearing parts:

the 'independent' unit: c_0_n * exp(-k_n * t),

the basic unit: f(a,b) = (exp(- k_n[b - 1] * t) - exp(- k_n[a - 1] * t)) / (k_n[a - 1] - k_n[b - 1]),

the nested unit based on the basic unit,

the product of the multiplication of constants (parameters) before each nested unit.

Each nested unit of the n-th equation derives from the nested units of the (n-1)-th equation. The equations themselves can be obtained through iterated integration. The number of possible equations (based on the number of independent kinetic constants k) for the n-th reagent is given by Bell number B(n).

Each such equation can be obtained from the equation with n independent kinetic constants for the n-th reagent (all are independent of one another). One simply has to find the limes of such equation. E.g. if k_3 = k_4 and k_7 = k_2, then we are looking for lim k_4->k_3 [lim k_7->k_2 (f(t))].

The working code:

print print ("Commands: komendy() - list of commands, test() - sets initial parameters, zakres() - asks for the number of reagents, tabela() - displays the table, stez() - asks for the initial concentrations, kin() - asks for the kinetic constants.") print n = 0 import matplotlib.pyplot as plt import numpy as np def komendy(): # displays the list of commands print print ("Commands: komendy() - list of commands, test() - sets initial parameters, zakres() - asks for the number of reagents, tabela() - displays the table, stez() - asks for the initial concentrations, kin() - asks for the kinetic constants.") print return def zakres(): # number of reagents query global n, zakres_n, c_0_n, k_n n = int(raw_input("Define the number of n reagents: ")) zakres_n = range(1, n + 1) c_0_n = [int(0)] * n k_n = [int(0)] * n return def stez(): # initial concentrations query while True: y = int(raw_input("Define the value of c_0_n for n equal to (press 0 to break): ")) if y == 0: break x = raw_input("Define the value of c_0_" + str(y) + ": ") if "." in x: c_0_n[y - 1] = float(x) else: c_0_n[y - 1] = int(x) return def kin(): # kinetic constants query while True: q = int(raw_input("Define the value of k_n for n equal to (press 0 to break): ")) if q == 0: break p = raw_input("Define the value of k_" + str(q) + ": ") if "." in p: k_n[q - 1] = float(p) else: k_n[q - 1] = int(p) return def tabela(): # displays the table with the initial data if n == 0: zakres() print print "n: ", zakres_n print "c_0_n: ", c_0_n print "k_n: ", k_n print else: print print "n: ", zakres_n print "c_0_n: ", c_0_n print "k_n: ", k_n print return def wykres(): # plots the basic unit global f_t, t_k, t, t_d a = int(raw_input("a = ")) b = int(raw_input("b = ")) reag = map(int, raw_input("Provide the reagents to plot (separate with spacebar): ").split(" ")) t_k = float(raw_input("Define time range from 0 to: ")) t_d = float(raw_input("Set the precision of the time axis: ")) t = np.arange(0,t_k,t_d) p = [] def f_t(t): return (np.exp(- k_n[b - 1] * t) - np.exp(- k_n[a - 1] * t)) / (k_n[a - 1] - k_n[b - 1]) f_t = f_t(t) for i in reag: p += plt.plot(t,i*f_t)

And the code that doesn't work [yet] (the only difference is the new wykres() function I'm trying to build):

print print ("Commands: komendy() - list of commands, test() - sets initial parameters, zakres() - asks for the number of reagents, tabela() - displays the table, stez() - asks for the initial concentrations, kin() - asks for the kinetic constants.") print n = 0 import matplotlib.pyplot as plt import numpy as np def komendy(): # displays the list of commands print print ("Commands: komendy() - list of commands, test() - sets initial parameters, zakres() - asks for the number of reagents, tabela() - displays the table, stez() - asks for the initial concentrations, kin() - asks for the kinetic constants.") print return def zakres(): # number of reagents query global n, zakres_n, c_0_n, k_n n = int(raw_input("Define the number of n reagents: ")) zakres_n = range(1, n + 1) c_0_n = [int(0)] * n k_n = [int(0)] * n return def stez(): # initial concentrations query while True: y = int(raw_input("Define the value of c_0_n for n equal to (press 0 to break): ")) if y == 0: break x = raw_input("Define the value of c_0_" + str(y) + ": ") if "." in x: c_0_n[y - 1] = float(x) else: c_0_n[y - 1] = int(x) return def kin(): # kinetic constants query while True: q = int(raw_input("Define the value of k_n for n equal to (press 0 to break): ")) if q == 0: break p = raw_input("Define the value of k_" + str(q) + ": ") if "." in p: k_n[q - 1] = float(p) else: k_n[q - 1] = int(p) return def tabela(): # displays the table with the initial data if n == 0: zakres() print print "n: ", zakres_n print "c_0_n: ", c_0_n print "k_n: ", k_n print else: print print "n: ", zakres_n print "c_0_n: ", c_0_n print "k_n: ", k_n print return def wykres(): # plots the requested functions global t_k, t, t_d, f, constans reag = map(int, raw_input("Provide the reagents to plot (separate with spacebar): ").split(" ")) t_k = float(raw_input("Define the time range from 0 to: ")) t_d = float(raw_input("Define the precision of the time axis: ")) t = np.arange(0,t_k,t_d) p = [] def f(a,b): # basic unit return (np.exp(- k_n[b - 1] * t) - np.exp(- k_n[a - 1] * t)) / (k_n[a - 1] - k_n[b - 1]) def const(l,r): # products appearing before the nested parts const = 1 constans = 1 for h in range(l,r): const = const * k_n[h] constans = c_0_n[l] * const return def czlonF(g): # nested part czlonF = 0 for u in range(g): czlonF = czlonF + npoch(f(a,b),g) if g == 1: czlonF(g) = 0 return def npoch(f(a,b),n): f = f(a,b) for x in range(b+1, n+1): f = npoch(f(a,b),x) return def c(j): # final result, concentration in time function return def czlon0(m): # 'independent' part return (c_0_n[m - 1] * np.exp(- k_n[m - 1] * t)) for i in reag: # the actual plot command p += plt.plot(t,c(i)) plt.show() return def test(): global n, zakres_n, k_n, c_0_n n = 5 zakres_n = range(1, n + 1) k_n = [1,2,3,4,5] c_0_n = [2,3,4,5,6] return plt.show() return def test(): global n, zakres_n, k_n, c_0_n n = 5 zakres_n = range(1, n + 1) k_n = [1,2,3,4,5] c_0_n = [2,3,4,5,6] return

Thank you for all your time!