# Take positive square root in Mathematica

I'm currently doing some normalization along the lines of:

``````J = Integrate[Psi[x, 0]^2, {x, 0, a}]
sol = Solve[J == 1, A]
A /. sol
``````

For this type of normalization, the negative square root is extraneous. The result of this calculation is:

``````In[49]:= J = Integrate[Psi[x, 0]^2, {x, 0, a}]
Out[49]= 2 A^2

In[68]:= sol = Solve[J == 1, A]
Out[68]= {{A -> -(1/Sqrt[2])}, {A -> 1/Sqrt[2]}}
``````

Even if I try giving it an Assuming[...] or Simplify[...], it still gives me the same results:

``````In[69]:= sol =  Assuming[A > 0, Solve[J == 1, A]]
Out[69]= {{A -> -(1/Sqrt[2])}, {A -> 1/Sqrt[2]}}

In[70]:= sol =  FullSimplify[Solve[J == 1, A], A > 0]
Out[70]= {{A -> -(1/Sqrt[2])}, {A -> 1/Sqrt[2]}}
``````

Can anyone tell me what I'm doing wrong here?

I'm running Mathematica 7 on Windows 7 64-bit.

-

`Solve` doesn't work like this. You might try `Reduce`, instead, e.g.

``````In[1]:= Reduce[{x^2 == 1, x > 0}, x]
Out[1]= x == 1
``````

It's then a little tricky to transform this output to replacement rules, at least in the general case, because `Reduce` might use arbitrary many logical connectives. In this case, we could just hack:

``````In[2]:= Solve[Reduce[{x^2 == 1, x > 0}, x], x]
Out[2]= {{x->1}}
``````
-

`ToRules` does what the box says: converts equations (as in `Reduce` output) to rules. In your case:

``````In[1]:= ToRules[Reduce[{x^2==1,x>0},x]]
Out[1]= {x->1}

In[2]:= {ToRules[Reduce[{x^2==1},x]]}
Out[2]= {{x->-1},{x->1}}
``````

For more complex cases, I have often found it useful to just check the value of the symbolic solutions after pluging in typical parameter values. This is not foolproof, of course, but if you know there is one and only one solution then it is a simple and efficient method:

``````Solve[x^2==someparameter,x]
Select[%,((x/.#)/.{someparameter-> 0.1})>0&]

Out[3]= {{x->-Sqrt[someparameter]},{x->Sqrt[someparameter]}}
Out[4]= {{x->Sqrt[someparameter]}}
``````
-
Great, thank! I'd forgotten about ToRules. –  Scott Morrison Jul 5 '10 at 12:52