Introduction to Theoretical Physics/Mathematical Foundations/Arithmetic, Physics, and Mathematics

Tentative outline for Arithmetic, Physics, and Mathematics; or the Units of Measurement

1. Physics and Mathematics begin with counting
   • 1 apple, 2 apples, etc.
   • Thus an "apple" in our records is a unit of measurement, the quantity in question being "number of apples"
2. This evolves into simple arithmetic
   • 1 apple added to 1 apple is 2 apples
   • 10 apples subtracted from 30 apples is 20 apples
3. Introduction of shorthand notation
   • ${\displaystyle 1apple+1apple=2apples}$
   • ${\displaystyle 30apples-10apples=20apples}$
4. Mathematics can discard the physical objects in question and has the luxury of concerning itself with abstract concepts
   • ${\displaystyle 1+1=2}$
   • ${\displaystyle (1+1)\times a=2\times a}$
   • ${\displaystyle 1\times a+1\times a=2\times a}$
5. Whereas in mathematics the constant ${\displaystyle a}$ represents a numerical constant, in physics this constant can represent a physical constant, thereby allowing physical objects to behave as mathematical entities in mathematical equations
   • ${\displaystyle 1\times apple+1\times apple=2\times apple}$
6. Units of measurements are important in mathematical equations since they represent critical information and errors in calculations will result if these physical constants are neglected
   • ${\displaystyle 1+1=2}$
     is wrong in the sense that
     ${\displaystyle 1\times apple+1\times orange=1\times apple+1\times orange}$
     is the only answer allowed under the rules of mathematics
7. Also, care must be taken when we perform mathematical operations
   • ${\displaystyle (3\times apples)\times (3\times apples)=9\times apple{s}^2}$
     represents 9 apples arranged in a square
   • ${\displaystyle (3\times apples)\times (3\times oranges)=9\times apples\times oranges}$
     creates a new physical quantity apple(orange) that is neither apples nor oranges! This is how new physical quantities, i.e. energy are created from lengths, times, and masses.

1. Time
   • Usually measured in seconds
     • Shorthand is s
       • 10 seconds
       • 10 s
   • Only unit of measurement not to be decimalized (although such a system does exist)
2. Distance
   • Usually measured in meters
     • Shorthand is m
       • 10 meters
       • 10 m
3. Mass
   • Base unit is the kilogram
     • Shorthand is kg
       • 10 kilograms
       • 10 kg
   • Sometimes measured in grams
     • Shorthand is g
       • 10 grams
       • 10 g

1. Area
   • Usually measured in meters squared
     • ${\displaystyle 10meters\times meters}$
     • ${\displaystyle 10squaremeters}$
     • ${\displaystyle 10{\text{m}}^2}$
2. Volume
   • Usually measured in meters cubed
     • ${\displaystyle 10meters\times meters\times meters}$
     • ${\displaystyle 10cubicmeters}$
     • ${\displaystyle 10{\text{m}}^3}$
3. Density
   1. Linear density
      • Usually measured in kilograms per meter
        • ${\displaystyle 10kilogramspermeter}$
        • ${\displaystyle 10\text{kg}/\text{m}}$
   2. Area density
      • Usually measured in kilograms per meter squared
        • ${\displaystyle 10kilogramspersquaremeter}$
        • ${\displaystyle 10\text{kg}/{\text{m}}^2}$
   3. Volumetric density
      • Usually measured in kilograms per meters cubed
        • ${\displaystyle 10kilogramspercubicmeter}$
        • ${\displaystyle 10\text{kg}/{\text{m}}^3}$

• Shorthand notation for large or tiny numbers based on powers of 10

1. Large
   • ${\displaystyle 1,000,000=10^6=1\times 10^6}$
   • ${\displaystyle 2,500,000=2.5\times 10^6}$
2. Small
   • ${\displaystyle 0.001=10^{-3}=1\times 10^{-3}}$
   • ${\displaystyle 0.000234=2.34\times 10^{-4}}$

• Further simplification of written numbers
  • ${\displaystyle 4,430\text{ meters}=4.43\times 10^3\text{ meters}=4.43\text{ kilometers}}$
  • ${\displaystyle 4,430\text{ m}=4.43\times 10^3\text{ m}=4.43\text{ km}}$

1. In mathematical equations, units of measurement behave as constants
   • ${\displaystyle (1\text{ m}+2\text{ m})\times 4\text{ m}=12{\text{ m}}^2}$
2. To convert from one unit of to another, we utilize an equation relating the two measurements
   • ${\displaystyle 1\text{ km}=1000\text{ m}}$
3. We can solve and substitute for the constant ${\displaystyle m}$
   • ${\displaystyle \frac{1}{1000}\text{ km}=\text{ m}}$
   • ${\displaystyle [1\left(\frac{1}{1000}\text{ km}\right)+2\left(\frac{1}{1000}\text{ km}\right)]\times 4\left(\frac{1}{1000}\text{ km}\right)=12{\left(\frac{1}{1000}\text{ km}\right)}^2}$
   • ${\displaystyle (1\times 10^{-3}\text{ km}+2\times 10^{-3}\text{ km})\times 4\times 10^{-3}\text{ km}=12\times 10^{-6}{\text{ km}}^2}$

The Mathematics of Conversion Between Units

  1. In mathematical equations, units of measurement behave as constants
         * (1\mbox{ m} + 2\mbox{ m})\times 4\mbox{ m} = 12\mbox{ m}^2
  2. To convert from one unit of to another, we utilize an equation relating the two measurements
         * 1\mbox{ km} = 1000\mbox{ m} \,
  3. We can solve and substitute for the constant m
         * \frac{1}{1000}\mbox{ km} = \mbox{ m}
         * \left[1\left(\frac{1}{1000}\mbox{ km}\right) + 2\left(\frac{1}{1000}\mbox{ km}\right)\right]\times 4\left(\frac{1}{1000}\mbox{ km}\right) = 12 \left(\frac{1}{1000}\mbox{ km}\right)^2
         * \left(1\times 10^{-3}\mbox{ km} + 2\times 10^{-3}\mbox{ km}\right)\times 4\times 10^{-3}\mbox{ km} = 12\times 10^{-6}\mbox{ km}^2

1. The derivative and small quantities
2. The integral and summation of infinite quantities

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