Why you can't mix x and y components of vectors?

In summary, vector addition does work--separately summing the magnitudes of the components does give the components of the sum vector.
  • #1
Shay10825
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Hi. Does anyone know of a proof that explains why you can't mix x and y components of vectors? For example you know how if you are solving a physics problem you have to break things up into x any y components (eg: velocity). My physics teacher wanted us to find a proof online that explained why you can't combine the x and y components of a velocity vector for example. I tried looking for a proof through google but i can't find one. So i wanted to know if any of you knew of a proof like this.

Thanks
 
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  • #2
If you are a little more exact on what you mean by "mix" and "combine", maybe I can help you. It is certainly possible to add the x and y components of a vector. You'll get a number alright, but it really won't mean much.
 
  • #3
whenever i do a physics problem i have to break things up into its components (x and y components). After you break it up if you for example add the components together that would be wrong because the components are independent of each other. I'm trying to find a proof that explains why that is true. I looked on google but i coulld not find anything.
 
  • #4
There is a correct way of adding the x and y components back into a single vector, but it is not just summing the the magnitudes of the components. Are you trying to prove that some particular method of adding the components is wrong? If so what is that method?
 
  • #5
I need a proof saying that summing the the magnitudes of the components is not the correct way of adding vectors
 
  • #6
Ha! That's a great question. The x and y components cannot be mixed (e.g. added together) because we assume that objects take the shortest route between two points, which is a straight line on the analytic (Cartesian) plane. Then we apply the Euclidian distance to the line between the two points, which is the hypothenus equality. For example, the Euclidian distance between point a = (xa,ya) and point b = (xb,yb) is [itex]\sqrt{(x_b-x_a)^2+(y_b-y_a)^2}[/itex].

But let's say that you need to calculate distance in a big city. The streets go in the West-East direction (the X axis) or the South-North direction (the Y axis). In this case, the shortest distance between any two points is the sum of the X component and the Y component. For example, the "street distance" between points a and b would be |xb - xa| + |yb - ya|. That's because the only way anyone can travel in a city is to cover the whole West-East distance first, and then cover the whole South-North distance (or the other way around). Any way you look at it, total distance traveled is the sum of the x component and the y component.

In my opinion the "proof" you are looking for is the hypothenus rule, which states that the length of the hypothenus is [tex]\sqrt{\text{base}^2+\text{height}^2}.[/tex]
 
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  • #7
lol, couldn't this only be done satisfactorily using linear algebra's completely general approach to vector spaces over R^3?


everything else would just be hand-wavy, as far as i know. :/


a safe bet would be "because they are perpindicular to each other."

i guess you could start getting fancy and say that the projection of a vector onto another perpindicular vector is zero, etc.

as my phys 2 prof said, "they're orthogonal--they're not talking to each other." (this was about real numbers and imaginary numbers, but the same general idea.)
 
  • #8
x and y are independent.
Since it is 2 dimenional, this becomes parametic equation problem. X and Y are related by the relation with t, but they are independent from each other.
but i bet it will still come out the same mathematically if you don't break it up... although this complicate the problem itself...

my largest bet would be that the vector analysis is developed BASED ON SUCH OBSERVATION, not the nature behavior acting based on vector analysis.
 
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  • #9
Shay10825 said:
I need a proof saying that summing the the magnitudes of the components is not the correct way of adding vectors
Actually, separately summing the magnitudes of different components does give you the components of the sum vector ! So, there's nothing wrong with it at all !

So, the only way to interpret your request is to show that summing the various components of a vector does not give its magnitude. This, however, is merely a result of definition. The magnitude (or norm) of a vector (in Euclidean space) is defined as the RMS value of the components. Why this definition is chosen (over say, simply adding the components) is seen from usefulness of defining the magnitude as the displacement from the origin.
 
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  • #10
It's not really a matter of proof. We decide to model things like velocity with vectors like ax + by + cz where {x, y, z} is linearly independent. The justification for this model would have to be empirical. Also, adding the magnitudes of two vectors is certainly not the right way to add vectors since |v| + |w| is not even a vector, it is a scalar.
 
  • #11
EnumaElish said:
The x and y components cannot be mixed (e.g. added together) because we assume that objects take the shortest route between two points, which is a straight line on the analytic (Cartesian) plane.

Oh, PLEASE tell me that's not what you really meant to write!
 

1. Why can't you add or subtract vectors with different dimensions?

Vector addition and subtraction involves adding or subtracting the corresponding components of two vectors. If the vectors have different dimensions, there will be missing components to add or subtract, resulting in an invalid operation.

2. Can you multiply two vectors with different dimensions?

No, vector multiplication is only defined for vectors with the same number of dimensions. In order to multiply two vectors, they must have the same number of components.

3. What happens if you try to find the dot product of two vectors with different dimensions?

The dot product is only defined for vectors with the same number of dimensions. If the vectors have different dimensions, the dot product cannot be calculated and the operation is invalid.

4. Why can't you compare vectors with different dimensions?

In order to compare vectors, they must have the same number of dimensions. If they have different dimensions, there will be missing components to compare, making it impossible to determine their relationship.

5. Is it possible to find the cross product of two vectors with different dimensions?

No, the cross product is only defined for vectors in three-dimensional space. If the vectors have different dimensions, they cannot be used to find the cross product.

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