Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I take a cash advance of 'amount' from my credit card, paying an up-front 'fee' (given as a percentage), with a promotional rate 'int' for time 'len'. I must pay at least 'min'% of the owed amount monthly.

I put 'amount' into an investment account earning 'p'% interest, and also make the monthly payments from this account.

Question: for what value of 'p' will I break even after time 'len'?

Here's how I set it up in Mathematica:

DSolve[{ 

(* I start off owing amount plus the fee *) 
owed[0] == amount*(1+fee), 

(* The amount I owe increases due to credit card interest, 
   but decreases due to monthly payments *) 
owed'[t] == int*owed[t]-min*12*owed[t], 

(* I start off having amount *) 
have[0] == amount, 

(* The amount I have increases due to investment interest, 
   but decreases due to monthly payments *) 
have'[t] == p*have[t]-min*12*owed[t], 

(* After len, I want to break even *) 
owed[len] == have[len] 
}, 
{owed[t], have[t]}, {t}] 

Mathematica returns "DSolve::bvnul: For some branches of the general solution, the given boundary conditions lead to an empty solution", which is actually reasonable: there's only one value of 'p' that will yield a solution for the differential equations above.

How do I coerce Mathematica into finding this value?

I tried solving for owed[t], then substituting owed[t] into have[t], and then solving owed[len] == have[len], but this yield a similar error. Running Reduce on "owed[len] == have[len]" yielded something complex and ugly.

share|improve this question
    
So far, my plan to coerce people into giving me better answers has not met with wide success ;) –  barrycarter Dec 16 '10 at 3:30
add comment

1 Answer

up vote 2 down vote accepted

The equation:

owed'[t] == int owed[t]-min 12 owed[t] 

if both int and min are constants, is just a exponential function. With the initial condition

owed[0] == amount*(1 + fee)  

gives

owed[t_] := amount E^((int - 12 min) t) (1 + fee)  

And that's the solution for owed[t]

Now for have[t] you may use:

DSolve[{
  have'[t] == p*have[t] - min*12*owed[t],
  have[len] == owed[len]},
 {have[t]}, {t}]  

That gives you the expression for have[t] that meets your break even condition.

For obtaining the value of p, you must use the last equation:

 have[0] == amount  

or, after replacing have[0] for it's value:

(amount E^(-len p) (1 + fee) (12 E^(len p) min + 
   E^(len (int - 12 min)) (-int + p)))/(-int + 12 min + p) == amount 

This last equation seems not easily solved for p. I tried a few things (not too much, certainly) and it resists strong.

But ... given numerical values for the rest of the parameters is trivially solved by any numerical method (I guess)

share|improve this answer
    
OK, so the crux here is that you can't put 'have[0] == amount' inside of DSolve, because there's no general solution. However, if you compute the general solution and then do 'have[0] == amount', you're fine. –  barrycarter Dec 16 '10 at 0:45
    
@barrycarter Well, I'm not sure why it doesn't work with "all inside", just tried to find a way out ... –  belisarius Dec 16 '10 at 0:55
    
Yes, thanks! I was just trying to figure out what I did wrong, and that appears to be it. –  barrycarter Dec 16 '10 at 0:56
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.