Start with something simple like: velocity * time = distanceAyesha_Sadiq said:But I still couldn't get what is implied when we multiply two physical quantities.
No, because it's 5N * 3m not 5N/m * 3m.Ayesha_Sadiq said:Then wouldn't a 5N times 3m be like 15 Newtons total force applied in 3 unit distances of 1m each.
Oh. But then what would division be in physics? I am guessing this is how relationships are developed between physical quantities. How physical quantities are sort of quantified relative to one another, and many factors considered at once. And it just all somehow works out.Phy_enthusiast said:In physics there is no thing as multiplication,there is only dot product or cross product.
Your example with candy is also a "rate" multiplication: candies per person, candies per package.Ayesha_Sadiq said:Thank you for the reference of the book. I'll try to get my hands on it as soon as possible. But then, in this case, wouldn't it be a somewhat 'rate' multiplication. Like, I am covering 2 metres per second, so how many metres I cover in 10 seconds would be a sort of 'rate' multiplication.
Velocity and time are both physical quantities.Ayesha_Sadiq said:Not of two physical quantities, would it?
Ayesha_Sadiq said:Oh. But then what would division be in physics?
Phy_enthusiast said:In physics there is no thing as multiplication,there is only dot product or cross product.
Thank you, I think this is what I was looking for. So, it's just Mathematics can describe relationships between physical quantities too, without it necessarily being a 'multiplication' of some sort.sophiecentaur said:The original concept of Multiplication would have been repeated integer addition. e.g. ten sheep with four legs gives you forty legs altogether. sheep plus sheep plus sheep etc.
Once the mechanics of this was established, it was found that you got the right answer if non-integers were involved. The history of Maths is full of instances of taking a basic operation and then finding it works in complicated situations.
The use of Maths to model the real world is an interesting point of philosophical discussion.
Ayesha_Sadiq said:Thank you, I think this is what I was looking for. So, it's just Mathematics can describe relationships between physical quantities too, without it necessarily being a 'multiplication' of some sort.
Everything about integers is more intuitive than continuous numbers. But multiplication of continuous numbers is not specific to physics.BruceW said:And so maybe this is the reason why multiplication of continuous numbers is much less intuitive than multiplication of integers, which can be thought of in terms of unions of sets.
neither is multiplication of the integers... I don't understand what you mean here. I didn't really mention physics because I thought that the OP's issue was more with the mathematical intuition.A.T. said:But multiplication of continuous numbers is not specific to physics.
Maybe, but she asks specifically about multiplication of physical quantities in the physics forumBruceW said:I didn't really mention physics because I thought that the OP's issue was more with the mathematical intuition.
I agree that multiplication of the reals does not have a direct link to your 'candy intuition'. I think most mathematicians would say the 'candy intuition' is one specific example of multiplication, and multiplication of continuous numbers is another specific example. I think 'multiplication' in maths is used as a very loose term. For example, multiplication of square matrices would be another specific example of a kind of multiplication.Ayesha_Sadiq said:So then, real, continuous numbers are multiplied that way, and it doesn't really mean what multiplication means generally.
Surely our ability to measure to arbitrary precision is a different issue? It looks like you are implying that if we could measure to arbitrary precision, then physical quantities would not take real value...Ayesha_Sadiq said:And I think physical quantities do take a real value, as we cannot measure them more than a specific degree of precision. And their actual value is really not what we measure, only a very, very close approximation, which works. I hope I am getting this right...?
BruceW said:Surely our ability to measure to arbitrary precision is a different issue? It looks like you are implying that if we could measure to arbitrary precision, then physical quantities would not take real value...
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sophiecentaur said:This problem with Multiplication is only the tip of the iceberg; the whole thing gives cause for concern. Everywhere we involve Calculus (Greek of an indivisible pebble, btw) we just accept the implication that the variable we are dealing with is continuous and often we further assume it is differentiable over its whole range etc. etc. Imagine someone came up with proof about the granularity of the Universe - we could still 'assume' continuity for most of our work.
I think the best idea is to separate the thing into two areas of worry. First of all, get to grip with the Maths and 'make it work' for you. Then, when you have time to spare, get into Mathematical Analysis - or whatever they call it these days and see how everything that (legit) Mathematicians do is justifiable, going back to simple stuff like 0+1 = 0 and 1X1 = 1. Trying to tie those two things together at every step can really spoil your day.
PS You are quite happy to sit and watch TV and use your computer and you probably have very little idea of the working details of those things. We do it all the time. Chill.
when I said 'real number' I mean the mathematical definition 'real number'. They have certain nice properties. In a sense, they 'fill up' the number line very tightly. So, for example, the set of all possible fractions is also infinite, but they don't fill up the number line as tightly as the real numbers do. So anyway, the 'real numbers' is the strict mathematical name for what we would usually call 'continuous numbers' in everyday talk.Ayesha_Sadiq said:Yes. Physical quantities do take real values, but we can only measure them to a specific degree of precision. Got no tools or instruments for that. =P No division on an instrument could be the smallest, you could go on making the smallest divisions smaller and smaller, and increasing it's precision. So then, a real value like that, would be a continuous number?
I agree, we don't perceive multiplication of continuous numbers like we do for integers. For integer multiplication, we have the 'candy intuition' that you mentioned. But for continuous numbers, I don't think we have any kind of intuition like that.Ayesha_Sadiq said:And we don't perceive multiplications of continuous numbers like we do for integers?
The concept of work done is the measure of the energy transferred to an object by applying a force over a certain distance. It is represented by the equation "work done = force x displacement". In simple terms, it is the amount of effort required to move an object a certain distance.
Work done is calculated by multiplying the magnitude of the force applied to an object by the distance it is moved in the direction of the force. This means that if there is no displacement or no force applied, no work is done.
The unit of work done is the joule (J), which is defined as the amount of work done when a force of 1 newton is applied over a distance of 1 meter in the direction of the force. Other common units include kilojoules (kJ) and calories (cal).
Yes, work done can be negative. This happens when the force applied and the displacement are in opposite directions. In this case, the work done is considered to be negative because the force is acting against the motion of the object, resulting in a decrease in its energy.
Work done and power are related by the equation "power = work done / time". This means that the same amount of work can be done in a shorter amount of time with more power, or in a longer amount of time with less power. Power is a measure of the rate at which work is done.