Errors and approximations in physical quantities

Physics is the science of measurement. We cannot learn science and its applications without measuring physical quantities. Thus measurement plays a vital role in the process of learning physics.

 While measuring physical quantities we always take some references and that references are being called as fundamental units. For example to measure the length we always use a meter scale. But every reference that we are taking will have its own limitations. If you consider a meter scale, the smallest reading that we can measure with that is millimeter. It is called the least count of the device. So this device is able to measure any length accurately up to 1 mm only. Hence we are having a compromise in measuring the reading. If you want an accuracy that is less than 1 mm, we shall use a better devise like vernier calipers.

Vernier calipers is a device which can measure the readings accurately up to 1/10 of the millimeter. If you are looking for a better accuracy we shall choose the devices like screw gauges who have an accuracy of one by hundreds of the millimeter.Every devise will have its own least count and we cannot measure accurately less than that using the device. So to what level we compromise in measuring in a reading simply depends on what is a requirement is. We appropriately choose the device as per our requirements.
Thus whatever the devise that we use to measure some physical quantities,the reading is prone to some sort of errors. Here we are going to discuss what are the types of possible errors are there and how can be contained within the possible limitations.

Error is the amount of uncertainty that is present in the measurement made with a measuring instrument. We always tries to either eliminate or minimize the errors. In many cases as it is not possible to eliminate the errors completely we try to minimize them using some mathematical and statistical methods.
Arithmetical mean is the one of that kind of the mathematical method to minimize the possible errors in a measurement. Here we measure the same reading multiple times and we take the mean of them.

Accuracy is the measure of the closeness of the measured value to the true value. It is obvious that the less the error  better the accuracy.
Precision refers to the agreement among the group of the measured values.If the measurement that we are making is consistent it will have a better appreciation and mean to say that all the readings will be very close to each other. Eliminating systematic errors can improve accuracy whereas repeating the experiment number of the Times can improve the precision.

Types of errors:
There are many reasons because of which get we errors. There are those that are always unidirectional are called systematic errors. Least count is a kind of the systematic error that occurs whenever you measure a particular reading with a particular instrument it is always prone to that least count error.

Environmental errors are quite possible as the conditions around experiments in the laboratory will be keep on changing. For example when we are doing an experiment parameters like pressure, temperature, humidity and wind velocity are always having a possibility of changing and because of this also we get some errors in the final readings.
There are some sort of errors called personal errors who comes the only due to the experimenter. This depends on how focused the experimenter and how careful he is while is taking the readings. Every experiment demand some sort of precautions and if they were not taken care, then also we get errors. A simple example of this kind of personal error is parallax error.This error comes because the readings are not taken by keeping the the object parallel to the eye.

To minimize the errors,we can take the arithmetic mean of all the readings. 
Random errors:

The errors which are irregular and whose cause is not known and random in nature in their sign and size are called random errors. There is no way that we can eliminate this kind of errors.The only possibility is to minimize them by using some mathematical methods like statistics.
An error is the difference between the measured value and the actual value.

Absolute error is the arithmetic mean of all their errors that were measured in different readings of an experiment.
Relative error is the ratio of absolute error to the actual value.

To get the percentage error,  we have to multiply the relative error with hundred.

 Combination of errors:
A physical Quantity in equation is because of some sort of mathematical operation like addition, subtraction, multiplication and division of some other physical quantities.When this kind of situation is there we have to deal with the combination of their errors in the  resultant.

In addition and  subtraction we always treat the total possible error as the sum of two errors in the given to physical quantities. By taking so we are preparing ourselves to the worst possible scenario so that we can use that readings quite safely. The same is the case of multiplication and division and how the errors are being taken in the process is described as shown in the diagram below.


When physical quantities are the result of rising the physical quantities  to certain powers than also there are possible errors and we can get the value of the error by differentiating the given equation as shown below.


Significant figures:
The digits of a number representing a measurement that are definitely known plus one more digit added at the end which is estimated are called significant digits are significant figures. There are certain rules to follow in determining the number of significant figures.
Rules for identifying significant figures:


  1. All nonzero digits given in a number are significant without any regard to the location of decimal points.
  2. All zeros occurring in between nonzero digits are significant.

  4. If a number is greater than one all the zeros right to the decimal point are significant.
  5.  all the zeros to the right of last nonzero digits after the decimal point are significant.
  6. If a number is not having a decimal point then all zeros to the right of last nonzero digit are not significant. 

  8. Anyway this rule is having an exception that if the reading comes because of an actual measurement who is having a unit then this zeros becomes significant.


Rounding off the number:

In any experimenter in practical life we don’t need so many significant figures which will make your calculation measurements lengthy. In that case we can reduce the number of the significant figures and make the reading more simple and the process is called rounding off.

The preceding digit has to be raised by one if the immediate insignificant is it to be dropped is more than five.
The preceding digit  need not be arise if the significant figure that you want to drop ease less than five.
If that is it that you want to drop is five itself then we have to look at the previous digit. If the previous digit is a even digit we can just leave it as it is otherwise we have to add one to the previous digit.


 Related Posts
No comments:
Labels: , , ,

Dimensional formula for a physical quantities and its Uses

Dimensional formula is a representation of the physical quantity in terms of fundamental quantities. By writing dimensional formula we are identifying how fundamental quantities are raised to different powers to get a new physical quantity. The powers of the fundamental physical quantities are called as dimensions.

We represent dimensional formulas in terms of length, mass and the time. Writing dimensional formula for any physical quantities is a easy task once if you know the concept behind that physical quantity. If you know the dependence of the physical quantity on the other physical quantities, with can write the dimensional formula quite easily. In dimensional formula Length shown with L, mass is shown with M and the time is shown with T.

Though many of the physical quantities consists of only this three fundamental quantities, it is quite possible that some of the physical quantities can have the representation of SI system fundamental physical quantities in the dimensional formula.

Some of the physical quantities and the way of writing their dimensional formulas are explained in a typical example below.



Different physical quantities may have the same dimensional formulas. We can only get a rough idea by looking at the physical quantities dimensional that what it is made up of in terms of fundamental quantities.We cannot judge everything about physical quantity just by looking at the dimensional formula alone. If that is the case learning about dimensional form itself is sufficient to interpret the entire physics itself.

Different physical quantities of quite different nature sometimes can have the same dimensional formula.For example work and torque are having the same dimensional formulas but the nature of the physical quantities is quite different.

It is quite possible that some of the physical quantities won't have any dimensional formulas.Examples are like angle, strain and coefficient of friction.

Principal of homogeneity:

Only physical quantities of the same nature having the same dimensions can be added, subtracted or can be equated. It is as simple as we need to add one velocity with another velocity to get another velocity. We cannot add velocity and displacement like we cannot add water and kerosene and get something productive.

It simply means the terms of the both sides of the dimensional equation shall have the same dimensions.

Applications of dimensional analysis:

  1. Dimensional formulas can be used to convert the physical quantities numerical value  from one system of units to other system of units.
  2. We can check the correctness of a given equation basing on dimensional analysis.
  3. We can derive the relation between different physical quantities using the dimensional analysis.
Explanation for the applications of dimensional analysis:

Here let us discuss how can we convert a physical quantities numerical value from one system to other. In a simple example here we would like to convert one jowl of energy is how many erg ?

In solving this problem we have simply taken a known relation to others that is discussed in the previous topic physical quantities under units. Larger the value of the unit smaller its multiplication factor.



In this step we would like to analyse how can we check the correctness of a given equation using dimensional analysis.In using this application we're taking a basic concept into consideration which is called as principal of homogeneity. The concept simply says that dimensional formula of the LHS side of a given equation shall be equal to its RHS side.




Here we are discussing another example of using the same concept. The concept is to check the relation between physical quantities using the principle of homogeneity.Whenever a equation is written in physics will be generally taking it for granted that it is satisfying the principle of homogeneity. By using the same concept of the below problem is solved.




Finally we would like to find the relation between physical quantities using the dimensional analysis. Here also we are going to use the same principle of homogeneity. When it is given that the physical quantity depends on some other physical quantities,we will simply write a proportional relation and equate dimensions of each fundamental physical quantities on the both the sides of the equation.




Limitations on the use of dimensional formulas:

  1. we cannot calculate the value of the proportionality constants using the dimensional analysis.
  2. Formulas containing non-algebraic functions like trigonometric functions and exponential functions cannot be derived basing on the dimensional analysis.
  3. To derive the relation between the physical quantities at least we need to have a rough idea of dependence of the physical quantities ,otherwise we cannot obtain the relation.
  4. We cannot derive a equation which contains two or more than two terms in the right-hand side of the equation using the dimensional analysis.

Related Posts


2 comments:
Labels: , ,

Measuring Physical Quantities with Units

Physics is a branch of sciences which deals with the study of the nature. In this subject measuring the physical quantity is very important. In physics something is meaningful,only when we are able to measure and express it with certain units and dimensions. 

 Whenever you're talking in terms of physics,we always think of how to measure a physical quantity. Thus measurement has a significant importance while we are studying physics.So to measure physical quantities we use units and to express physical quantities we use dimensional formulas.

We can divide the entire physical quantities broadly into two categories. The physical quantities which are independent of any of the other physical quantities are called as fundamental quantities. Some simple examples of the fundamental quantities are like length mass and time. It is as simple as that time is not going to depend on any other physical quantities.

The physical quantities which are derived basing on the fundamental quantities are called as derived physical quantities. displacement,velocity,acceleration and force are some of the derived physical quantities.

To measure this physical quantities we use units. There are different systems of units to measure physical quantities. If the scale of the measurement in any physical quantity is large, then the corresponding numerical value will be small. For example if you want to measure the length of your body in terms of meters and in terms of centimeters, it's numerical value will be less in terms of meters when compared with centimeters. It is simply because the unit meter is a large unit, the length of the body appears to be small in number.




 There are different systems of units in which the physical quantities can be measured. Among them F.P.S system,C.G.S system and M.K.S systems are prominent ones. All these three systems are actually used to measure three fundamental quantities length, Mass and time. In the following table the comparison of the three different kinds of systems is described.



In FPS system,to measure length measures we use the unit foot and to measure mass we use with the unit called Pound. The problem in measuring the length with feet, is not having a sort of consistency. Whenever we are adopting a unit as a standard unit, it shall be universal, easily reproducible, accessible for everybody, and standard so that everybody can follow easily. As feet is being inconsistent and varies from person to person in terms of size, we are no more preferring the unit feet.

In CGS system there is a small issue in measuring the length with the unit called centimeter. This unit is too small to measure long distances. Hence we have introduced another system called MKS system. For many years MKS system is being used as a standard system.

As science has been developed with respect to time it has been notice that there are some other physical quantities which are also independent in nature. By taking them into consideration, a new system called standard international system is designed. This system has length, Mass and the time as the fundamental physical quantities similar to MKS system. 

 It also has new physical quantities like electric current which is measured with the unit called Ampere, temperature, intensity of light and quantity of matter. There are two more supplementary physical quantities like angle and solid angle. All this physical quantities are together are called as standard international system. Right now we are following this system to measure all the physical quantities that are existing around us.





Rules in writing units:

  1. If a unit is measured in the name of scientists and when it is written in full name we shall not start the unit with a capital letter.
  2. When you are writing the symbol of a unit in the name of a scientists it has to be represented with a capital letter in a single letter.
  3. No punctuation marks Shall be used at the end of the units.
  4. Unit shall be always expressed in singular but not in plural.
Related Posts

1 comment:
Labels: , , , ,
Subscribe to: Posts (Atom)