Take a number like 3+3i. It is a point at x=3 and y=3 and you can put that on graph
paper. With the proper software or program, you can graph more complex formulas
like (z-1)/(z+1). Look at the related link. It is one version of two like charges or two
like magnet poles near each other.
It's actually quite hard to graph complex numbers - you would need a four-dimensional space to graph them adequately. I believe it's more convenient to find zeros analytically for such functions.
This is a graph of the numbers by the complex number formula (z-1)/(z+1) Refer to the related link.
"Color wheel graphs" are commonly used. At each point in the complex plane, the graph is a color, where the brightness represents the magnitude, and the hue represents the complex angle. Thus, positive values are cyan, negative values are red, and pure imaginary values are green or magenta. Other complex numbers are mixtures of these. Zero is black, and infinity is white. (Other schemes are also in use)
You can't just simply "get" a complex graph. I think what you are trying to say is how can you find a complex graph. Well, you go to Google and type in "complex graph". If you want to be more specific, then type in the specific thing you are researching. THERE! That is the solution!
On a graph, the activation energy represents the minimum energy required for a reaction to occur. The activated complex is the unstable intermediate state during a reaction. The reaction rate is influenced by the activation energy and the stability of the activated complex. A lower activation energy and a more stable activated complex typically result in a higher reaction rate.
Take a number like 3+3i. It is a point at x=3 and y=3 and you can put that on graph paper. With the proper software or program, you can graph more complex formulas like (z-1)/(z+1). Look at the related link. It is one version of two like charges or two like magnet poles near each other.
For example, the conjugate of 5 + 3i is 5 - 3i. The graph of the first number is three units above the real number line; the second one is three units below the real number line.
Yes, a complex number can be graphed on a two-dimensional plane known as the complex plane. The real part of the complex number corresponds to the x-axis, while the imaginary part corresponds to the y-axis. The complex number is represented by a point in the complex plane, with its coordinates being the real and imaginary parts. The distance of the point from the origin represents the magnitude of the complex number.
The idea of graphing complex numbers was published by Argand in 1806. See related link.
I believe that a vertical line of a graph is simply X=any real number. Real Number- a rational number or the limit o a sequence of any rational numbers, not to be confused with a complex number.
The mathematical technique used to calculate the area under a graph is integral calculus. This is a complex subject which I am not going to attempt to explain in detail- it normally takes years of study.
Displaying data in a graph allows for easier visualization and comparison of trends and patterns, making it simpler to understand complex information at a glance.