Physics Notes - Units of Measurement

Summary

These notes provide an introduction to units of measurement in physics. They explain the importance of standardized units, the SI base units, and various conversion methods. It also covers scientific notation to express large and small numbers.

Full Transcript

# Physics

## Lesson 1.1 Units of Measurement

### Measurement

* In the past, Egyptians and Babylonians use their body parts to estimate the length of an object.
* A process of assigning a quantity to describe a property of an object by comparing it with a standard.
* A standard should be universal and does not change with time.

### International System or SI

* It is a standard system of measurement for the fundamental quantities. Abbreviated from Système International. Also called as "metric system".

### SI Base Units

| Quantity | Symbol | SI unit | Symbol |
|---|---|---|---|
| Time | t | Second | s |
| Length | 1, x, r | Meter | m |
| Mass | m | Kilogram | kg |
| Electric Current | I, i | Ampere | A |
| Thermodynamic Temperature | T | Kelvin | K |
| Amount of Substance | n | Mole | mol |
| Luminous Intensity | Iv | Candela | cd |

#### Second

> The time required for 9,192, 671, 170 cycles of microwave radiation in cesium-137 atoms.

#### Meter

> The distance traveled by light in a vacuum in 1/299, 792, 458 sec.

#### Kilogram

> Define by taking the fixed numerical value of Planck constant h to be 6.62607015 \* 10^-34 J\*s.

#### Ampere

> The numerical value of the elementary charge e (1.602176634 \* 10^-19 C).

#### Kelvin

> Fixed numerical valve Boltzmann constant k to be 1.380 649 \* 10^-23 J\*K^-1, equivalent to kg\*m^2\*s^-2\*K^-1.

#### Mole (mol)

> One mole contains exactly 6.022 140 76 \* 10^23 elementary entities. Fixed value of Avogadro constant.

#### Candela (cd)

> The luminous efficacy of monochromatic radiation with frequency of 540 \* 10^12 Hz, ked, to be 683 lm\*W^-1, when expressed in the unit Im\*W^-1 equal to cd\*sr\*W^-1 or cd\*sr\*kg^-1\*m^-2\*s^3.

## Conversion of Units

* Units can be treated as algebraic quantities that can cancel each other.

**Example:**

Suppose you want to convert 5.0 inches to centimeters given that 1 inch is equivalent to 2.54 centimeters.

5.0 in = (5.0 in \* 2.54 cm) / in = 12.7 cm

* The unit inch is placed in the denominator so that it cancels the unit from the original value.
* The remaining unit "centimeter" is the desired result.

## Lesson 1.2 Scientific Notation and Scientific Figures

### Scientific Notation

* Very large and very small numbers can be expressed using scientific notation sometimes called powers of 10 notation. All numbers can be expressed in the form of equation 1.2.1.

### Addition and Subtraction of Scientific Notation.

* To add and subtract, make sure that the expressions have similar terms.

**Ex:** 8.5 \* 10^3 kg + 3.6 \* 10^3 kg (common factor 10^3)

(1) (8.5 \* 10^3 kg) \* (3.6 \* 10^3) =
(8.5 + 3.6) x 10^3 kg

(2) (8.5 + 3.6) x 10^3 kg = 9.1 x 10^3 kg

**If exponents are not the same**

**Ex:** 5.5 \* 10^3 kg + 3.6 \* 10^5 kg.

(1) 10^5 (larger exponent) can be written as 10^2 \* 10^3. Therefore,
3.6 \* 10^5 = 3.6 \* 10^2 \* 10^3 kg =
(3.6 \* 10^2) \* 10^3 kg = 360 \* 10^3 kg

(2) Factor out the common factor
(5.5 \* 10^3 kg) + (360 \* 10^3 kg) =
(5.5 + 360) x 10^3 kg

(3) Add N
(5.5 + 360) x 10^3 kg = 365.5 x 10^3 kg

### Multiplication and Division with Scientific Notation

* In multiplying, calculate the dimensions of:

**Ex:** 1.5 \* 10^2 m \* 2.1 \* 10^4 m

(1) 1.5 * 2.1 = 3.15

(2) Add the exponents, 10^2 * 10^4 = 10^6

(3) 3.15 * 10^6 m^2

* In Division, Ns are divided as is, while the exponents are subtracted.

**Ex:** 2.1 \* 10^4 m / 1.5 \* 10^2 m

(1) 2.1 / 1.5 = 1.4
(2) Subtract exponent: 10^4 - 10^2 = 10^2
(3) 1.4 \* 10^2 m

## Lesson 1.3 Uncertainties and Deviations in Measurement

### Measurement

* **Error:** difference between the true value and the measured value.
* **Uncertainty:** net effect of error; quantifies the doubt that exists in any reported value of the measurement.

### Accuracy and Precision

* **Accuracy:** indicates how close the measured value to the true value.
* **Precision:** describes the scatter or the variability of a set of measurements made.

## Lesson 1.4 Sources and Types of Error in Measurement

### Errors in Measurement

* In measurement, error signifies an inevitable uncertainty that is present in all types of error.
* It cannot be completely eliminated even if one is conducting an experiment carefully.

### Two main types of error:

* **Systematic error**
* **Random error**

#### Random Error

* Occur when repeated measurements produce randomly different results.
* Observed after repeated measurements.

#### Systematic Error

* Errors that remains constant or changes in regular fashion even if measurements are repeated.

### Types of Scattering in Experiments:

* **Fundamental Noise**
* **Technical Noise**

#### Fundamental Noise

* Can you control the behavior of the launcher?
* Can you control how the ball as it is launched by the launcher?

#### Technical Noise

* How does minute changes in the angle by which the ball launch affect your data?

### Mistakes

* Similar in nature to systematic errors and are also difficult to detect.
* **Least Count:** smallest division found in a measuring device.

### Error Bars

* Graphical representations indicating the range of uncertainty of a specific value or data.

## Lesson 2.1 Scalar and Vector Quantities

### Physical Quantities

* **Two types of physical quantities:**

* **Scalar quantities**
* **Vector quantities**

#### Scalar quantities

* A physical quantity that has magnitude (size of quantity) but no direction.
* Temperature is a scalar quantity.
* Described by a single number with its appropriate unit.
* Other examples are mass, time, distance, speed, density, volume.

#### Vector quantity

* A physical quantity with both magnitude and direction.
* Magnitude describes the size or the size of the physical quantity while Direction describes how the vector is oriented relatives to a reference point.

### Representing Vector Quantities

* Vectors are represented by a single letter with an arrow above them.
* **Speed** - scalar quantity
* **Velocity** - vector quantity

### Magnitude of vectors

* Magnitude of vectors is represented by the same letter used in a vector quantity
* Magnitude of *v* = |*v*|

* The shortest distance is defined as displacement
* Displacement is a vector, it is represented by an arrow.
* The length of the arrow represents the vectors magnitude.

## Lesson 2.2 Vector addition through Graphical Method

### Vectors in One Dimension

* If two vectors are pointing in the same direction its parallel if two vectors have opposite directions but have the same magnitude its anti-parallel.

### Subtracting of Vectors

A + (-B) = A - B

## Lesson 2.3 Components of Vectors

* Sin θ = opp/hyp = Ay/A
* Cos θ = adj/hyp = Ax/A
* Tan θ = opp/adj = Ay/Ax
* Ax = A cos θ
* Ay = A sin θ

**Ex:** What are the x- and y- components of a displacement vector with a magnitude of 50 m and an angle of 30°?

50 cos (30) = x component - 43.30 m
50 sin (30) = y component - 25 m

**Ex:** a car has a displacement of 750 m, 45° north of west. What are the components of a displacement vector?

750 sin (45) = x component - 530.37 m
750 cos (45) = y component - 530.37 m

### Step 1: Determine whether the angles given were measured from the +x-axis

> **Vector A is 10m, 20° NE**
> **Vector B is 15m, 50° NE**

### Step 2: Resolve each vector into its x- and y- components

* Ax = A cos θ
* Ay = A sin θ

### Step 3: Add all components together

* Rx = Ax + Bx
* Ry = Ay + By

### Step 4: Calculate the magnitude of the vector using Pythagorean theorem.

R = √R²x + Ry²

R = √R²x + R²y = √(19.04m)² + (4.91m)² = 24. 18 m

> The resultant vector of Denise is 24.18m, 19.04°, or 38.06 ° NE

## Lesson 2.4 Vector Addition through Analytical Method

* Vectors can be added by placing them head to tail.
* Graphical method, however, is prone to measurement errors

**Ex. Word problem:**

Denis walks everyday from her house to the school. Fist, she covers 10m, 20° north of east. Then, she walked 15m in a direction 50° north of east. What is her resultant displacement?

## Lesson 2.5 Vector Multiplication

### Scalar Product

* The scalar product of a vector and another vector will result in a scalar quantity.
* It is also referred to as a dot product.

* A \* B = AB cos Φ

* **When can the scalar product be positive?**
* **When can the scalar product be negative?**
* **When can the scalar product be zero?**

* **What happens when vectors are parallel?**

A \* B = AB cos 0 = AB

* **What happens when vectors are anti parallel?**

A \* B = AB cos 180 = - AB

### Scalar Product Laws

* **Commutative Law**
A \* B = B \* A
* **Distributive Law**
A \* (B + C) = A \* B + A \* C

**Ex:** Find the scalar product between the two vectors if the magnitude of A is 9.0 and B is 15.0 and the angle between them is 45°.

The scalar product is 95.

**Ex:** Find the magnitude of vector A if the scalar product between A and B is 30 m, the magnitude of B is 10 m, and the angle between the vectors is 60°.

The magnitude of A is 6 m.

**Ex:** Find the angle between the two vectors A and B with magnitudes 16 and 4, respectively. The scalar product of the two vectors is 10.

The angle between the two vectors is 71.17° or 70°.

### Vector Product

* The following properties apply to vector product.

* **Anticommutative Property**
A \* B = - B \* A

* **Distributive Law**
A \* (B + C) = A \* B + A \* C

* **Magnitude of A \* B also equals B (A sin Φ).**
* **Magnitude of B) \* (Component of A perpendicular to B)**