Does anyone know how to express two primes such that $P=\frac{4k^3}{(k+m)^3}+\frac{6k^2}{(k+m)^2}+\frac{4k}{(k+m)}+1,$ where all numbers are nonzero integers?
Primes expressible as $\frac{4k^3}{(k+m)^3}+\frac{6k^2}{(k+m)^2}+\frac{4k}{(k+m)}+1$ for $k,m\geq1$
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0Here is an example p=5 k=1 m=1 – 2011-12-17
1 Answers
Here is a start:
$P=\frac{4k^3}{(k+m)^3}+\frac{6k^2}{(k+m)^2}+\frac{4k}{(k+m)}+1$
Means
$p(k+m)^4= 4k^3(k+m)+6k^2(k+m)^2+4k(k+m)^3+(k+m)^4 \,.$
Adding $k^4$ on both sides you get
$p(k+m)^4+k^4=\left( k+(k+m) \right)^4 \,.$
Thus
$P(k+m)^4=(2k+m)^4-k^4=(2k+m-k)(2k+m+k)((2k+m)^2+k^2)$
or
$P(k+m)^3=(3k+m)(5k^2+4km+m^2) \,.$
You can probably work from here by looking to the gcd $(k+m, 3k+m)$.
If $k,m$ are positive, the following is a simple continuation:
$(3k+m) < 3(k+m)$ $5k^2+4km+m^2 < 5k^2+10km+5m^2=5(k+m)^2 \,.$
Thus, $P < 10$.
Now, for each $p \in \{ 2,3,5,7 \}$ the equation
$P(k+m)^3=(3k+m)(5k^2+4km+m^2) \,.$
is a cubic equation in $\frac{m}{k}$, you are asking when it has a rational solution.... you can solve it numerically for each case.
Alternate route
Consider $P$ a parameter, and use the cubic formula to solve
$4x^3+6x^2+4x+(1-p)=0 \,.$
If $x= \frac{k}{m+k}$ is an irreducible solution, then $k|p-1$ and $m+k |2$.
Without loss of generality, you can assume that $m+k >0$.
Then $m+k =1$ or $m+k=2$.
If $m+k=1$ then we get
$4k^3+6k^2+4k+1-p=0 \,;$
with $k$ integer
while
If $m+k=2$ then we get
$k^3+3k^2+4k+2-2p =0 \,.$
with $k$ integer.
The cubic formula should help, but probably someone will see something smarter...