i am trying to learn matlab.
I am trying to make a program that draw these imaginary numbers: ("," = decimal number)
and determine what of the 500 numbers that is closest the real axis.
And i need a little guidance.
What do i have to do to solve this task?
I was thinking about making a loop where all the "values" get stored in a array:
[code]
n= 1
while n < 500
value=1+0.1^n;
disp(value)
n=n+1[/code]
(seems like value is printing wrong values? and how to store in a array?)
And then somehow determine what number that is nearest the real axis and then display the value.
would be really grateful if someone could help me.
thanks in advance.
MATLAB creates imaginary numbers by appending an i or j term with the number. For example, if you wanted to create an imaginary number such that the real component was 1 and the imaginary component was 1, you would simply do:
>> A = 1 + i
A =
1.0000 + 1.0000i
You can see that there is a distinct real component as well as an imaginary component and is stored in A. Similarly, if you want to make the imaginary component have anything other than 1, you would need to add a constant in front of the i (or j). Something like:
>> A = 3 + 6i
A =
3.0000 + 6.0000i
Therefore, for your task, you simply need to create a vector of n between 1 to 500, input this into the above equation, then plot the resulting imaginary numbers. In this case, you would plot the real component on the x axis and the imaginary component on the y axis. Something like:
>> n = 1 : 500;
>> A = (1 + 0.1i).^n;
>> plot(real(A), imag(A));
real and imag are functions in MATLAB that access the real and imaginary components of complex numbers stored in arrays, matrices or single values. As noted by knedlsepp, you can simply plot the array itself as plot can handle complex-valued arrays:
>> plot(A);
Nice picture btw! Be mindful of the . operator appended with the ^ operator. The . means an element-wise operation. This means that we wish to apply the power operation for each value of n from 1 to 500 with 1 + 0.1i as the base. The result would be a 500 element array with the resulting calculations. If we did ^ by itself, we would be expecting to perform a matrix power operation, when this is not the case.
The values that you want to analyze for each value of n being applied to the equation in your post are stored in A. We then plot the real and imaginary components on the graph. Now if you want to find which numbers are closest to the real axis, you simply need to find the smallest absolute imaginary component of the numbers stored in A, then search for all of those numbers that share this number.
>> min_dist = min(abs(imag(A)));
>> vals = A(abs(imag(A)) == min_dist)
vals =
1.3681 - 0.0056i
This means that the value of 1.3681 - 0.0056i is the closest to the real axis.
Related
I was looking for a way to generate a logarithmic spaced array in IDL.
From the L3 Harris Geospatial website I came across "arrgen" and was trying to use it for this purpose. However,
arrgen(1,215,/log)
returns the error: Variable is undefined: ARRGEN.
What would be the correct way to do it?
Thanks in advance for your help
Start by defining your lower and upper bounds in which ever log-base you prefer. I will use base $e$ for brevity sake.
lowe = ALOG(low[0])
uppe = ALOG(upp[0])
where low and upp are scalar, numerical values you, the user, define (e.g., 1 and 215 in your example). Then construct an evenly spaced array of n elements, such as:
dinde = DINDGEN(n[0])*(uppe[0] - lowe[0])/(n[0] - 1L) + lowe[0]
where n is a scalar integer. Now convert back to linear space to get:
dind = EXP(dinde)
This will be a logarithmically spaced array. If you want to use base-10 log, then substitute ALOG for ALOG10. If you need another base, then you can use the logarithmic change of base rule given by:
logb x = logc x / logc b
This is probably a trivial question, but I want to select a portion of a complex array in order to plot it in Matlab. My MWE is
n = 100;
t = linspace(-1,1,n);
x = rand(n,1)+1j*rand(n,1);
plot(t(45):t(55),real(x(45):x(55)),'.--')
plot(t(45):t(55),imag(x(45):x(55)),'.--')
I get an error
Error using plot
Vectors must be the same length.
because the real(x(45):x(55)) bit returns an empty matrix: Empty matrix: 1-by-0. What is the easiest way to fix this problem without creating new vectors for the real and imaginary x?
It was just a simple mistake. You were doing t(45):t(55), but t is generated by rand, so t(45) would be, say, 0.1, and t(55), 0.2, so 0.1:0.2 is only 0.1. See the problem?
Then when you did it for x, the range was different and thus the error.
What you want is t(45:55), to specify the vector positions from 45 to 55.
This is what you want:
n = 100;
t = linspace(-1,1,n);
x = rand(n,1)+1j*rand(n,1);
plot(t(45:55),real(x(45:55)),'.--')
plot(t(45:55),imag(x(45:55)),'.--')
I have 3 graphs of an IV curve (monotonic increasing function. consider a positive quadratic function in the 1st quadrant. Photo attached.) at 3 different temperatures that are not obtained linearly. That is, one is obtained at 25C, one at 125C and one at 150C.
What I want to make is an interpolated 2D array to fill in the other temperatures. My current method to build a meshgrid-type array is as follows:
H = 5;
W = 6;
[Wmat,Hmat] = meshgrid(1:W,1:H);
X = [1:W; 1:W];
Y = [ones(1,W); H*ones(1,W)];
Z = [vecsatIE25; vecsatIE125];
img = griddata(X,Y,Z,Wmat,Hmat,'linear')
This works to build a 6x6 array, which I can then index one row from, then interpolate from that 1D array.
This is really not what I want to do.
For example, the rows are # temps = 25C, 50C, 75C, 100C, 125C and 150C. So I must select a temperature of, say, 50C when my temperature is actually 57.5C. Then I can interpolate my I to get my V output. So again for example, my I is 113.2A, and I can actually interpolate a value and get a V for 113.2A.
When I take the attached photo and digitize the plot information, I get an array of points. So my goal is to input any Temperature and any current to get a voltage by interpolation. The type of interpolation is not as important, so long as it produces reasonable values - I do not want nearest neighbor interpolation, linear or something similar is preferred. If it is an option, I will try different kinds of interpolation later (cubic, linear).
I am not sure how I can accomplish this, ideally. The meshgrid array does not need to exist. I simply need the 1 value.
Thank you.
If I understand the question properly, I think what you're looking for is interp2:
Vq = interp2(X,Y,V,Xq,Yq) where Vq is the V you want, Xq and Yq are the temperature and current, and X, Y, and V are the input arrays for temperature, current, and voltage.
As an option, you can change method between 'linear', 'nearest', 'cubic', 'makima', and 'spline'
Is there some advantage of writing
t = linspace(0,20,21)
over
t = 0:1:20
?
I understand the former produces a vector, as the first does.
Can anyone state me some situation where linspace is useful over t = 0:1:20?
It's not just the usability. Though the documentation says:
The linspace function generates linearly spaced vectors. It is
similar to the colon operator :, but gives direct control over the
number of points.
it is the same, the main difference and advantage of linspace is that it generates a vector of integers with the desired length (or default 100) and scales it afterwards to the desired range. The : colon creates the vector directly by increments.
Imagine you need to define bin edges for a histogram. And especially you need the certain bin edge 0.35 to be exactly on it's right place:
edges = [0.05:0.10:.55];
X = edges == 0.35
edges = 0.0500 0.1500 0.2500 0.3500 0.4500 0.5500
X = 0 0 0 0 0 0
does not define the right bin edge, but:
edges = linspace(0.05,0.55,6); %// 6 = (0.55-0.05)/0.1+1
X = edges == 0.35
edges = 0.0500 0.1500 0.2500 0.3500 0.4500 0.5500
X = 0 0 0 1 0 0
does.
Well, it's basically a floating point issue. Which can be avoided by linspace, as a single division of an integer is not that delicate, like the cumulative sum of floting point numbers. But as Mark Dickinson pointed out in the comments:
You shouldn't rely on any of the computed values being exactly what you expect. That is not what linspace is for. In my opinion it's a matter of how likely you will get floating point issues and how much you can reduce the probabilty for them or how small can you set the tolerances. Using linspace can reduce the probability of occurance of these issues, it's not a security.
That's the code of linspace:
n1 = n-1
c = (d2 - d1).*(n1-1) % opposite signs may cause overflow
if isinf(c)
y = d1 + (d2/n1).*(0:n1) - (d1/n1).*(0:n1)
else
y = d1 + (0:n1).*(d2 - d1)/n1
end
To sum up: linspace and colon are reliable at doing different tasks. linspace tries to ensure (as the name suggests) linear spacing, whereas colon tries to ensure symmetry
In your special case, as you create a vector of integers, there is no advantage of linspace (apart from usability), but when it comes to floating point delicate tasks, there may is.
The answer of Sam Roberts provides some additional information and clarifies further things, including some statements of MathWorks regarding the colon operator.
linspace and the colon operator do different things.
linspace creates a vector of integers of the specified length, and then scales it down to the specified interval with a division. In this way it ensures that the output vector is as linearly spaced as possible.
The colon operator adds increments to the starting point, and subtracts decrements from the end point to reach a middle point. In this way, it ensures that the output vector is as symmetric as possible.
The two methods thus have different aims, and will often give very slightly different answers, e.g.
>> a = 0:pi/1000:10*pi;
>> b = linspace(0,10*pi,10001);
>> all(a==b)
ans =
0
>> max(a-b)
ans =
3.5527e-15
In practice, however, the differences will often have little impact unless you are interested in tiny numerical details. I find linspace more convenient when the number of gaps is easy to express, whereas I find the colon operator more convenient when the increment is easy to express.
See this MathWorks technical note for more detail on the algorithm behind the colon operator. For more detail on linspace, you can just type edit linspace to see exactly what it does.
linspace is useful where you know the number of elements you want rather than the size of the "step" between them. So if I said make a vector with 360 elements between 0 and 2*pi as a contrived example it's either going to be
linspace(0, 2*pi, 360)
or if you just had the colon operator you would have to manually calculate the step size:
0:(2*pi - 0)/(360-1):2*pi
linspace is just more convenient
For a simple real world application, see this answer where linspace is helpful in creating a custom colour map
I have a large data set with two arrays, say x and y. The arrays have over 1 million data points in size. Is there a simple way to do a scatter plot of only 2000 of these points but have it be representative of the entire set?
I'm thinking along the lines of creating another array r ; r = max(x)*rand(2000,1) to get a random sample of the x array. Is there a way to then find where a value in r is equal to, or close to a value in x ? They wouldn't have to be in the same indexed location but just throughout the whole matrix. We could then plot the y values associated with those found x values against r
I'm just not sure how to code this. Is there a better way than doing this?
I'm not sure how representative this procedure will be of your data, because it depends on what your data looks like, but you can certainly code up something like that. The easiest way to find the closest value is to take the min of the abs of the difference between your test vector and your desired value.
r = max(x)*rand(2000,1);
for i = 1:length(r)
[~,z(i)] = min(abs(x-r(i)));
end
plot(x(z),y(z),'.')
Note that the [~,z(i)] in the min line means we want to store the index of the minimum value in vector z.
You might also try something like a moving average, see this video: http://blogs.mathworks.com/videos/2012/04/17/using-convolution-to-smooth-data-with-a-moving-average-in-matlab/
Or you can plot every n points, something like (I haven't tested this, so no guarantees):
n = 1000;
plot(x(1:n:end),y(1:n:end))
Or, if you know the number of points you want (again, untested):
npoints = 2000;
interval = round(length(x)/npoints);
plot(x(1:interval:end),y(1:interval:end))
Perhaps the easiest way is to use round function and convert things to integers, then they can be compared. For example, if you want to find points that are within 0.1 of the values of r, multiply the values by 10 first, then round:
r = max(x) * round(2000,1);
rr = round(r / 0.1);
xx = round(x / 0.1);
inRR = ismember(xx, rr)
plot(x(inRR), y(inRR));
By dividing by 0.1, any values that have the same integer value are within 0.1 of each other.
ismember returns a 1 for each value of xx if that value is in rr, otherwise a 0. These can be used to select entries to plot.