Electric field between two charges

Question

The Problem Data

Q1      P     Q2
+ -----------  -
      40.0cm

$Q_1 = +50.0 \mu C$
$Q_2 = -10.0 \mu C$
$d(Q_1, Q_2) = 40.0 cm\ \ \ d(x,y) = distance\ between\ x\ and\ y$

I don't know for sure, it's not in the problem description, but I guess $P$ lies in the middle between $Q_1$ and $Q_2$.

Question

Calculate the electric field size in $P$.

What I've tried

Nothing really, I just don't know how to start.

Thank you in advance, I'm sure this will be far to easy for you guys!

Edit:

As I was asked if I knew how to solve it if one of the electric charges would be zero, I hereby want to tell I do.

I know:
$F = k \cdot \frac{|Q_1] \cdot |Q_2]}{r^2}$
$E = \frac{F}{|Q_t|}\ \ \ \ (Q_t = test\ charge)$
$= k \cdot \frac{|Q_s| \cdot |Q_t|}{r^2|Q_t|}\ \ \ \ (Q_s = source\ charge; Q_t = test\ charge)$
$= k \cdot \frac{|Q_s|}{r^2}$

Note: test charge and source charge are a free translation of 'proeflading' and 'bronlading' (Dutch/Flemish).

Answer 1

Keeping this general, I think the important principle is superposition which leads to my prescription below:

Electric fields are caused by charges, at a point the total electric field is equal to the sum of the fields caused by each charge being considered (superposition). Therefore to answer any general question like this I would recommend, counting your charges, working out the individual contributions seperately, then summing them.

Be carfeul with signs!

Answer 2

Let's see Two Charges $q_1$ and $q_2$, We have to find electric field at some point between them.

Let's assume $d$ to be the distance between the charges, which is constant and $x$ (from the center of the line joining the two charges, $\frac{d}{2}$ from the chagres) to be the distance where we want to measure electric field at.

                           |      x
        O------------------|------|-----------O
       q_1                 |                 q_2 
                           |

Now, $\large E_{q_1x} = \frac{1}{4 \pi \epsilon} \frac{q_1}{\left(\frac{d}{2}+x\right)^2}$ and $\large E_{q_2x} = \frac{1}{4 \pi\epsilon} \frac{q_2}{\left(\frac{d}{2}-x\right)^2}$

Total Electric Field at $x$,

$$E_{x} = \frac{1}{4 \pi \epsilon} \frac{q_1}{\left(\frac{d}{2}+x\right)^2} + \frac{1}{4 \pi\epsilon} \frac{q_2}{\left(\frac{d}{2}-x\right)^2}$$

I tried to make it as generalized as possible so you don't have to face problems with such type of problems in future. I hope it helps you and Good Luck for your Exam!

I tried to attach a picture but because of low reputation I couldn't, Sorry.