- #1
Parbat
- 29
- 0
What does "time" really mean?
What does "time" really mean?
i really don't know that.
What does "time" really mean?
i really don't know that.
Last edited by a moderator:
Parbat said:i mean,how can we say "time" is a dimension?
& dimension means something that is required to explain any object,is that true?
TheAlkemist said:Thanks for asking this question Parbat!
How can time be a dimension? What I was taught in physics:
A dimension is "the least number of COORDINATES required to specify, uniquely, a point in a space."
So is a dimension the same as a coordinate? I thought dimensions were related to ARCHITECTURE, STRUCTURE and ORIENTATION (shape, geometry) and coordinates were used to specify the LOCATION of things.
In 3D space, the dimensions are LENGTH, WIDTH and HEIGHT, pointing outwards from the object. The coordinates are LONGITUDE, LATITUDE and ALTITUDE and they point inwards, towards the object because the specify location. The corresponding VECTORS would be DEPTH, BREADTH and ELEVATION which specify the mutually orthogonal DIRECTIONS the object moves. Dimensions and coordinates are static while vectors are dynamic. The only attributes common to these three concepts are direction and orthogonality which are QUALITATIVE attributes. That's it.
So how does time fit into this? How is time considered a dimension when it's routinely used--by mathematicians, as a NUMBER LINE--to QUANTIFY?
Time is a one-dimensional quantity used to sequence events, to quantify the durations of events and the intervals between them, and (used together with space) to quantify and measure the motions of objects.
http://en.wikipedia.org/wiki/Time
So if time is a QUANTIFIER of a sequence of events, where/how does the QUALITATIVE attribute of directionality orthogonality come in here? Or is this merely an attribute that mathematicians (or Einstein) added to create a model/manifold for doing the math? (Minkowski Space-time?)
I don't get it. In science, don't we have to be objective and consistent with the terms (verbs, nouns, adverbs, adjectives) we use as per their definitions? Is't this required to maintain coherence and eliminate the ambiguity often encountered when metaphors are used? Isn't this what distinguishes science from other subjective forms of inquiry (like religion)?
I appologize for the lengthiness/dimension of this post. :tongue:
TheAlkemist said:So if time is a QUANTIFIER of a sequence of events, where/how does the QUALITATIVE attribute of directionality orthogonality come in here? Or is this merely an attribute that mathematicians (or Einstein) added to create a model/manifold for doing the math? (Minkowski Space-time?)
I don't get it. In science, don't we have to be objective and consistent with the terms (verbs, nouns, adverbs, adjectives) we use as per their definitions? Is't this required to maintain coherence and eliminate the ambiguity often encountered when metaphors are used? Isn't this what distinguishes science from other subjective forms of inquiry (like religion)?
What do you mean by "analyze a situation"? I'm going to assume that you mean how you describe an event occurring between (at least) two objects?ghwellsjr said:Everything you have said is excellent, but you stopped to soon. You should also have said that your choice of co-ordinate system should not make any difference in how you analyze a situation, don't you agree?
Why? If you don't muddle qualifiers and quantifiers there shouldn't be a problem. You should be able to objectively qualitatively define the distance between 2 objects in space by the relationship between their coordinates AND further define that distance relationship using a quantifying concept. My issue is in the packaging. When you start assigning attributes like directionality to abstract concepts like time. It's like talking about the direction of love, anger, or the color blue. these are all concepts which only have meaning in the context of the relationship between at least two objects. Eg., anger vs sadness, love vs hate, red vs blue, etcWell, that's the problem. When we try to define the distance between to events, widely separated in distance and time, we will get different answers for every co-ordinate system we use and that's no fun.
No. Sound like convenient mathematical magic to me. "Abra-kadabra!"... now a scalar is a vector!So to solve this problem we use a new kind of vector that includes both the normal three-component vector for space and the normal scalar for time, and we call it a four-vector. Then we invent (or discover) a way to calculate a new "distance" called "interval" that is always the same, no matter which co-ordinate system we use to describe, characterize, or analyze any situation.
Does that make sense to you?
TheAlkemist said:People often use these terms interchangeably. They talk about the length of time and concepts like 'time dilation'. What does this mean? You can only distort the SHAPE of an OBJECT. So is time an object?
Again, if these are only metaphors then how can this "science" objective? These circular definitions just introduce avenues for all kinds of circular arguments. What good science shouldn't allow.
I agree with you, there shouldn't be a problem, but unfortunately, Mother Nature doesn't agree with us and, so, we lose. It does make a difference which co-ordinate system we use and there is no way for us to determine which one is the correct one, so that is why we use the four-vector interval.TheAlkemist said:Why? If you don't muddle qualifiers and quantifiers there shouldn't be a problem. You should be able to objectively qualitatively define the distance between 2 objects in space by the relationship between their coordinates AND further define that distance relationship using a quantifying concept. My issue is in the packaging. When you start assigning attributes like directionality to abstract concepts like time.
-Your descriptions are confusing and overly complicated.TheAlkemist said:The coordinate system specifies the locations of the objects.
The dimension system specifies the shapes of the objects.
The vector system specifies the motion of the objects.
Coordinates and dimensions and vectors are all concepts used to qualify the situation. At this point, yes, it should make no difference how you analyze the situation if you stay consistent with these systems.
However...in order to quantify the situation we invented another abstract concept called numbers. Specifically number lines. And herein lies the mysterious merger of quantifying and qualifying concepts--numbers (quantifier) and lines (geometric qualifier) respectively. At which point numbers (with magnitude) have now inherited directionality. Vectors inherit magnitude, time inherits directionality.
-Time is a scalar (number/magnitude) and thus has no direction. The time variable was mathematically manipulated for the purpose of treating it as another dimension.Why? If you don't muddle qualifiers and quantifiers there shouldn't be a problem. You should be able to objectively qualitatively define the distance between 2 objects in space by the relationship between their coordinates AND further define that distance relationship using a quantifying concept. My issue is in the packaging. When you start assigning attributes like directionality to abstract concepts like time. It's like talking about the direction of love, anger, or the color blue. these are all concepts which only have meaning in the context of the relationship between at least two objects. Eg., anger vs sadness, love vs hate, red vs blue, etc
-A vector/tensor/matrix can contain any number of mixed type of values/attributes, as long as the values are manipulated in a consistent manner. Eg. A personal 'vector' (name, height, weight, eye color, etc...), useful in an employee database.This is not a trivial issue of semantics. When we use words in science, we must use them consistently as an objective criterion.
No. Sound like convenient mathematical magic to me. "Abra-kadabra!"... now a scalar is a vector!
Not saying it's useless, it just makes no real life physical sense.
-Processes, mechanical, chemical, etc. are mediated by light. Light speed is constant in space and independent of its origin. When objects such as clocks move, the associated processes slow down. The clock slices time into longer intervals, therefore the clock readings are relative for the observer moving with the clock.post#9:
People often use these terms interchangeably. They talk about the length of time and concepts like 'time dilation'. What does this mean? You can only distort the SHAPE of an OBJECT. So is time an object?
-Science can only measure real world processes, create conceptual models that mimic reality, and keep the ones that are successful. The concepts science uses are all ideal metaphors, just as images are not the objects in the image. We experience the world indirectly.Again, if these are only metaphors then how can this "science" objective? These circular definitions just introduce avenues for all kinds of circular arguments. What good science shouldn't allow.
How can you distort a force? A force has no shape and isn't physical object. You can only distort physical objects that have shape. If you're talking about distorting the vector (or tensor) that describes a force then that's a figurative statement. Just like the statement; "spreading love".Time Machine said:I could be very much mistaken, but you can distort the shape of a force.
Does this mean time is a force?
Please excuse me if I am way off here. I do get your circular arguments comment, but isn't that how new concepts are born?
Please explain. I'm confused.ghwellsjr said:I agree with you, there shouldn't be a problem, but unfortunately, Mother Nature doesn't agree with us and, so, we lose. It does make a difference which co-ordinate system we use and there is no way for us to determine which one is the correct one, so that is why we use the four-vector interval.
If it works so good why is gravity a problem? Why aren't the SM and GR compatible? Does this have anything to do with the mathematical formulations of these models? Just asking. Thanks.Time is placed orthogonal to the three components of space in the "imaginary" direction and it works and that is why we do it. If you don't like it you need to come up with another scheme that works but you can't stick to the one you have because it doesn't work.
Actually they are very simple and objective. I never said that numbers were not used to express magnitudes. They are and very useful at that. But, how can you use an informal definition on the one hand and then incorporate it into a formal definition on the other and hope to maintain consistency when trying to describe things objectively? When you rely on circular definitions and assume synonyms doesn't this confuse things? I thought math was about formal objective descriptions? I know science is supposed to be. Just because this is how people have been doing it since history doesn't make it correct.phyti said:-Your descriptions are confusing and overly complicated.
Numbers were/are used for expressing magnitudes, and have been for all of human history. Distances were/are expressed informally as magnitudes with a direction, and formally as vectors.
Do you agree that an object is made up of discrete atoms/particles separated by (a very very considerable amount of) space? I think most of the physics community does. If so, then which coordinates of what particle are you measuring from to determine the length of the object?The length of an object is the difference between the coordinates of the ends of the object.
I disagree. Coordinates describe location/position. Dimensions describe shape/structure. Above you said that length is the difference between coordinates of the ends. If you're now saying coordinates = dimensions then you're saying length is the difference between the dimensions of the ends. This makes absolutely NO sense. How is a dimension a "spatial interval"?There is no difference between coordinates and dimensions, they are both spatial intervals.
Could I well it magic then? Because this mathematical manipulation has created a physical thing from concept. A number changes to an object. Only objects have direction. I'm not being facetious.-Time is a scalar (number/magnitude) and thus has no direction. The time variable was mathematically manipulated for the purpose of treating it as another dimension.
Fair enough. How consistently and objectively do you think your so-called personality vector can be applied? I have strong doubts that it can. But I have a few computer science buddies working on AI that would be earger to know.-A vector/tensor/matrix can contain any number of mixed type of values/attributes, as long as the values are manipulated in a consistent manner. Eg. A personal 'vector' (name, height, weight, eye color, etc...), useful in an employee database.
The clock slices time? Since you can only slice through a continuous object, then are you suggesting that time is a continuous? But yoou say time is a dimension and you said above that dimensions are spatial intervals. So are you slicing through the intervals? I'm confused.-Processes, mechanical, chemical, etc. are mediated by light. Light speed is constant in space and independent of its origin. When objects such as clocks move, the associated processes slow down. The clock slices time into longer intervals, therefore the clock readings are relative for the observer moving with the clock.
Fair enough. I have no issue with metaphors. We can't avoid them as they're pervasive in everyday life. It's the consistency and potential for ambiguity and circular arguments that I have issue with. And by what criteria do you measure success?-Science can only measure real world processes, create conceptual models that mimic reality, and keep the ones that are successful. The concepts science uses are all ideal metaphors, just as images are not the objects in the image.
In special and general relativity time for an observer is simply the length between two events that cross his worldline, this length is physically measured by a clock. O more generally it is the calculated length between two events with a timelike distance between them over an arbitrary pathParbat said:What does "time" really mean?
i really don't know that.
TheAlkemist said:Actually they are very simple and objective. I never said that numbers were not used to express magnitudes. They are and very useful at that. But, how can you use an informal definition on the one hand and then incorporate it into a formal definition on the other and hope to maintain consistency when trying to describe things objectively? When you rely on circular definitions and assume synonyms doesn't this confuse things? I thought math was about formal objective descriptions? I know science is supposed to be. Just because this is how people have been doing it since history doesn't make it correct.
TheAlkemist said:Distance and length are NOT synonymous. There is a non-trivial,
qualitative difference between length and distance. Length is used to describe the shape of a continuous object. Distance is used to describe the space between 2 indivisible objects. Look up the definition of distance in any standard English dictionary and that's the definition you'll get; the space between two things.
Do you agree that an object is made up of discrete atoms/particles separated by (a very very considerable amount of) space? I think most of the physics community does. If so, then which coordinates of what particle are you measuring from to determine the length of the object?
I disagree. Coordinates describe location/position. Dimensions describe shape/structure. Above you said that length is the difference between coordinates of the ends. If you're now saying coordinates = dimensions then you're saying length is the difference between the dimensions of the ends. This makes absolutely NO sense. How is a dimension a "spatial interval"?
See what I mean.
I agree with the general gist of what you've said, except the red highlighted. In science, I think it's even more important to be as objective as possible in practical situations.phyti said:-The reference to informal use is to emphasize that a rigid definition is not needed for practical applications. Travel directions can be very general, eg., 10 miles down route 7 just past Wal-Mart. Scientific study obviously requires more rigid definitions with minimum ambiguity. My reply to the op's question about the meaning of time... it depends on the context. So it goes with definitions, it depends on the purpose.
Here's part of a paper on knowledge which mentions your concern about circular reasoning.
To form knowledge the mind;
--perceives reality,
--forms concepts to model reality,
--predicts reality from these concepts,
--keeps the concepts as knowledge when prediction matches reality.
--modifies the concepts after more perception
knowledge is a set of concepts used as a reference for understanding
By definition knowledge is always incomplete because all reality is never perceived.
For simplicity, a concept is defined within a context that excludes other concepts.
--Other concepts may not be relevant to the purpose.
--There may be relevant concepts that have not been created.
--An approximate definition may be sufficient for the purpose.
Definition is a relative referencing process.
--A definition is expressed in terms of other definitions.
--This process can be circular or incomplete.
Forming knowledge is a continuous process of refinement.
Knowledge is only as good as its definition.
coordinates specify the location or position of one thing. What you described is simply using a ruler to measure the length of a shape. It has nothing to do with coordinates.phyti said:Chemistry and quantum theory demonstrate that matter is discrete, 2 yeses.
Coordinates are measured from a common origin (by definition).
Three dimensions are sufficient for simple rectangular solids.
1. Place a ruler with the 'o' mark at one end and read the value 10 where the other end contacts the ruler. The length is 10-0=10.
2. Place the ruler with the '4' mark at one end and read the value 14 where the other end contacts the ruler. The length is 14-4=10.
You can't measure space. You measure objects in space. You can only talk about the distance between 2 objects in space. But not the length of space. Length is an attribute reserved for shapes.The only difference is where you designate the origin. You are still measuring space.
If 3 4" widgets are end to end, we have 12" of widgets. If the middle one is removed, there is still 4" of space between the other 2, whether it's occupied or not!
TheAlkemist said:coordinates specify the location or position of one thing. What you described is simply using a ruler to measure the length of a shape. It has nothing to do with coordinates.
You can't measure space. You measure objects in space. You can only talk about the distance between 2 objects in space. But not the length of space. Length is an attribute reserved for shapes.
And you said: "The length of an object is the difference between the coordinates of the ends of the object." and then... "The only difference is where you designate the origin."
Which is what I'm asking you. What exact point (coordinate position/location) in the solid object you're measuring, are you designating as the origin?
OK. I see where the issue is now. It's a question of matter, space, discreteness and coherence. Which might be outside the scope of this forum? I don't know.phyti said:When you measure the length of an object, you're measuring the space between the molecule at one end and the molecule at the other end. Whether there is matter in between them is irrelevant.
Objects 1,2, and 3 are small diameter spheres positioned inline. d= center to center distance.
Measure d1 between objects 1 and 2.
Measure d2 between objects 2 and 3.
S is the sum d1+d2. Isn't S the total distance/space between objects 1 and 3?
good one:rofl:yuiop said:Space is what prevents everything being in the same place and time is what prevents everything happening at the same time. :tongue:
Most laypersons? I thought an event was a dynamic thing...something that happens over some period of time. An occurrence. So are you saying time is a coordinate? Someone else said it was a "dimension". Now I'm really confused.Informally most laypersons think of coordinates as specifying a physical location, but in physics, coordinates specify an event, which specifies a location and a time. For example, you might arrange a meeting for next Monday, 10AM in the conference room, then the event is clearly defined and there is a greater chance of actually meeting than if the place or the time are left out.
If there are no fence posts and you're the only one in this void of space how would you measure velocity? Also, if velocity is measured as change in position with time you have to measure the time elapsed as you move somehow don't you? Or are you suggesting that you can measure velocity without measuring /recording time?As has already been said, space and time are both specify intervals between events. When you think really hard about it, spatial distance can be just as mysterious as time. For example, when walking down a road you might gauge the distance by counting fence posts, but what about gauging distance crossing a great void in space where there are no fence posts? One way to do that would be to measure your velocity and then time how long it takes to cross the void, or similarly you might send a radar signal across the void and work out the distance from how long it takes the signal to return.
This is an interesting point you bring up. But I would have to disagree. What's more fundamental here is motion. Space and motion being the most fundamental concepts. Time is a results from the motion of space (or more popularly, things in space).Thought of like this, it is easy to see that time and space are intimately related. Consider a hermit that never leaves his cave. You might think it is easy to specify his physical location without specifying a time, but it turns out that this is not true. His physical location in July is different to his physical location in December because the Earth has moved to the other side of the Sun in that time. His physical location in December 2009 is different to his physical location in December 2010 because the Sun has moved a short way around the Galaxy in that time. It becomes clear that the physical location of our apparently stationary hermit is time dependent.
No! The premise of your argument is false. You don't measure the length of an object by subtracting coordinates. Especially an object in motion! What you've described is simply a measurement of the DISTANCE between two positions; one occupied by the front of a moving object @ 1PM and the other occupied by the back of the moving object at 2PM. Concluding the LENGTH of the object from this DISTANCE is wrong!This intimate relationship between time and spatial distance even extends to the simple measurement of a length of an object. Let us say we have an object that in one metre long. If the object is moving relative to us and we measure the physical location of the front of the object at 1PM and the physical location of the back of the object at 2PM and subtract the two measurements, then we might conclude that the object is a mile long.
Sure. If you chose to measure the length of the object as the difference between two coordinates that specify positions at the ends of the object in some calibrated coordinate space then fine. But this would only make sense in the case of a static object. When you move the object the coordinates of the ends change. If you wana determine the length of the object using the coordinates you'd have to stop the object.Clearly, to make a sensible measurement of the moving object's length, we have to specify that the spatial coordinates of the ends of the objects are measured at the same time, or allow for the velocity and the time difference of the coordinates to calculate the proper length and so even the simple measurement of the length of a humble object requires we take time into our considerations.
What exactly do you mean by coordinate component? An Galileo even said motion was more fundamental than time. Heck, motion was his shtick.Time has always been a part of Galilean coordinates and making time a coordinate component is not a new invention of Einstein or relativity. Relativity just complicates things by demanding that you also specify who's time measurement is being used to specify an event, because time in relativity is not universal as in Newtonian physics.
It must be an interesting world you live in then. Or should I say...Godswitch said:... the past then becomes the present ...
Exactly. That's why theses notions of divided time always fall to the paradox of Zeno.Godswitch said:Time has 3 basic elements
Past - Present - Future
Both the present and future elements can be altered, the past is always constant
Of course you could argue the Past is not always a constant element because time itself is always moving forward so the past then becomes the present and so on
lolDaveC426913 said:It must be an interesting world you live in then. Or should I say...
.neht ni evil uoy dlrow gnitseretni na eb tsum tI
TheAlkemist said:How can you distort a force? A force has no shape and isn't physical object. You can only distort physical objects that have shape. If you're talking about distorting the vector (or tensor) that describes a force then that's a figurative statement. Just like the statement; "spreading love".
I'm not saying the concept of force is useless of meaningless because it's not!
New concepts should be born from scientific methodology so that the language used to describe them is as objective as possible. For example the concept, viscosity. Viscosity describes how forces change the dimensions of a fluid using corresponding vectors. You never hear people talking about "distorting" the viscosity of a fluid. You distort the shape of the fluid by changing the dimensions that describe its state.
This makes more sense to me.
Please explain. I'm confused.
If it works so good why is gravity a problem? Why aren't the SM and GR compatible? Does this have anything to do with the mathematical formulations of these models? Just asking. Thanks.
TheAlkemist said:What exactly do you mean by coordinate component? An Galileo even said motion was more fundamental than time. Heck, motion was his shtick.
No. The converse is true. Time doesn't exist outside of the dynamics (motion) of matter. Motion is how we humans experience, perceive and interpret periodicity. When you understand this it will be very clear and obvious to u.khemist said:That doesn't make any sense. Without time, there is no motion. However, the converse is not true. Even if there is no motion, time can still be effecting the object. We can do this by setting a particular object at the center of a particular coordinate system.
Dimensions might be "a convenient way" to specify location but I think is flawed. In science, dimensions specify the shape and structure of matter. Coordinates specify the location of matter. In our 3D world, we have a coordinate system of determining the position of an object with respect to longitude, latitude and altitude. You are conflating two separate systems; dimensions and coordinates.Dimension is a convenient way to specify how many numbers (or anything else) are needed to tell an objects location in a particular coordinate system. For example, in an N-Dimensional coordinate system (N being any real number) there are N coordinates needed to have a location. We CAN have some of those coordinates be zero, in which case the "space" that the vector is in is isomorphic to another space. If I have one vector, the "space" it is in, called a vector space, is isomorphic to R^1, because a vector is a straight line.
If I have 2 vectors, v = <1,1,0> and u = <0,1,0>, and I span those vectors on, in this case, because I have 3 coordinates, I have a 3 dimensional coordinate system (R^3), while the SPAN is in fact isomorphic to R^2, although the vector space created by the span is still in R^3.
I hope this helps...
I agree with ONLY the red highlighted if u add "the effect of" between "simply" and "a".edit: I guess this doesn't even come close to answering the OP's question.
From what I understand, time is simply a passage of events, or a coordinate in our 3+1 dimensional world (3 spatial + 1 time). I think what you might be attempting to ask is what makes time go, or why does the arrow of time always point the same direction (although it might not be the same magnitude). It could have to do with entropy, though my knowledge in this is not as strong. Maybe in a year or so I can help more :P
this is one of the several MATHEMATICAL definitions of 2-dimensions. This is NOT a scientific definition.cshum00 said:I love these forums because it always moves away from answering the original post. I try to give it a shot into answering the original question.
The original post question is: Why is time a dimension?
Let's first try to define what dimension is. Let's start with 2 dimensions. 2-dimensions in mathematics can be represented as 2 axis perpendicular to each other. If we add another dimension, we can visually think of it as adding a third axis orthogonal (orthogonal is the same as perpendicular except that perpendicular is a word only used for 2-dimensions) to the existing 2-dimensions.
This is incorrect and misleading. I'm a scientist. When we say space we simply mean...space. Space is that which has no shape or dimension. An object's shape can be specified or characterized by 3 dimensions; length, width and height, in space. These are parsimonious scientific definitions. Now if mathematicians by whatever convenient convention choose to call this "3-D space", whatever. IMO, the term "spatial dimension" is a misnomer.What confuses people is when scientists say that adding an extra dimensions is the same as adding extra "space" or degree of freedom into the picture. When scientists say space, they don't mean the physical space where you can put an real and physical object. They mean the mathematical meaning of space where you have an extra axis which you can represent graphically in a sheet of paper. When scientists say 2-dimensions in space, they only mean 2-axis perpendicular to each other which you can graphically plot and nothing physical in real-life.
Scientists don't say this. Well...good scientists at least. Treating time as a dimension may not be controversial in the establishment but it's certainly self-contradicting and leads to irrational conclusions.So, when scientists say that time is a spatial dimensions; they mean that it is useful for the mathematics to have an extra axis to analyze on a graph how time relates to other axes which could be distance, force, velocity, etc. Treating time as a dimensions is not controversial as you can see.
Which is why using it as a dimension is irrational. And mathematics does this not physics.What is rather counter-intuitive, is that physics treats time not only as a independent variable but also as a dependent variable. Meaning, that time is no longer universal but the value of it can be changed and influenced by other factors. In the case of special relativity in physics, time can be changed by the 3 other dimensions of distance.
ghwellsjr said:Wasn't this covered in my post #11 and #6 as well as many others?
ghwellsjr said:I agree with you, there shouldn't be a problem, but unfortunately, Mother Nature doesn't agree with us and, so, we lose. It does make a difference which co-ordinate system we use and there is no way for us to determine which one is the correct one, so that is why we use the four-vector interval.
Time is placed orthogonal to the three components of space in the "imaginary" direction and it works and that is why we do it. If you don't like it you need to come up with another scheme that works but you can't stick to the one you have because it doesn't work.
TheAlkemist said:Please explain. I'm confused.
If it works so good why is gravity a problem? Why aren't the SM and GR compatible? Does this have anything to do with the mathematical formulations of these models? Just asking. Thanks.