Difference between revisions of "EGR 103/Concept List Spring 2020"
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\(
y=e^x=\sum_{n=0}^{\infty}\frac{x^n}{n!}
\)
\(
\begin{align}
y_{init}&=1\\
y_{new}&=y_{old}+\frac{x^n}{n!}
\end{align}
\)
(→Lecture 15 - Review) |
|||
(2 intermediate revisions by the same user not shown) | |||
Line 186: | Line 186: | ||
</math> | </math> | ||
* See Python version of Fig. 4.2 and modified version of 4.2 in the Resources section of Sakai page under Chapra Pythonified | * See Python version of Fig. 4.2 and modified version of 4.2 in the Resources section of Sakai page under Chapra Pythonified | ||
+ | |||
+ | == Lecture 9 - Dictionaries and Loading == | ||
+ | <html> | ||
+ | <iframe src="https://trinket.io/embed/python/73b00fe165" width="100%" height="400" frameborder="0" marginwidth="0" marginheight="0" allowfullscreen></iframe> | ||
+ | </html> | ||
+ | |||
+ | == Lecture 10 - Monte Carlo Methods == | ||
+ | * From Wikipedia: [https://en.wikipedia.org/wiki/Monte_Carlo_method Monte Carlo method] | ||
+ | * See file in "Programs From Class" folder under Resources on Sakai | ||
+ | |||
+ | == Lecture 11 - Binary and Floating Point Numbers == | ||
+ | * Different number systems convey information in different ways. | ||
+ | ** Roman Numerals | ||
+ | ** Chinese Numbers | ||
+ | ** Binary Numbers | ||
+ | *** We went through how to convert between decimal and binary | ||
+ | ** [https://en.wikipedia.org/wiki/Kibibyte Kibibytes] et al | ||
+ | * "One billion dollars!" may not mean the same thing to different people: [https://en.wikipedia.org/wiki/Long_and_short_scales Long and Short Scales] | ||
+ | * Floats (specifically double precision floats) are stored with a sign bit, 52 fractional bits, and 11 exponent bits. The exponent bits form a code: | ||
+ | ** 0 (or 00000000000): the number is either 0 or a denormal | ||
+ | ** 2047 (or 11111111111): the number is either infinite or not-a-number | ||
+ | ** Others: the power of 2 for scientific notation is 2**(code-1023) | ||
+ | *** The largest number is thus just *under* 2**1024 (ends up being (2-2**-52)**1024<math>\approx 1.798\times 10^{308}</math>. | ||
+ | *** The smallest normal number (full precision) is 2**(-1022)<math>\approx 2.225\times 10^{-308}</math>. | ||
+ | *** The smallest denormal number (only one significant binary digit) is 2**(-1022)/2**53 or 5e-324. | ||
+ | ** When adding or subtracting, Python can only operate on the common significant digits - meaning the smaller number will lose precision. | ||
+ | ** (1+1e-16)-1=0 and (1+1e-15)-1=1.1102230246251565e-15 | ||
+ | ** Avoid intermediate calculations that cause problems: if x=1.7e308, | ||
+ | *** (x+x)/x is inf | ||
+ | *** x/x + x/x is 2.0 | ||
+ | |||
+ | == Lecture 12 - Matrix Operations == | ||
+ | * 1D arrays are neither rows nor columns - they are 1D! | ||
+ | * 2D arrays have...two dimensions, one of which might be 1 | ||
+ | * Dot products as heart of matrix multiplication | ||
+ | ** Inner dimensions must match; outer dimensions equal dimensions of result | ||
+ | * Reformatting linear algebra expressions as matrix equations | ||
+ | * Calculating determinants and inverses | ||
+ | ** Shortcuts for determinants of 1x1, 2x2 and 3x3 matrices (see class notes for processes) | ||
+ | ::$$\begin{align*} | ||
+ | \mbox{det}([a])&=a\\ | ||
+ | \mbox{det}\left(\begin{bmatrix}a&b\\c&d\end{bmatrix}\right)&=ad-bc\\ | ||
+ | \mbox{det}\left(\begin{bmatrix}a&b&c\\d&e&f\\g&h&i\end{bmatrix}\right)&=aei+bfg+cdh-afh-bdi-ceg\\ | ||
+ | \end{align*}$$ | ||
+ | :* Don't believe me? Ask [https://www.youtube.com/watch?v=ROFcVgehEYA Captain Matrix]! | ||
+ | * Inverses of matrices: | ||
+ | ** Generally, $$\mbox{inv}(A)=\frac{\mbox{cof}(A)^T}{\mbox{det}(A)}$$ there the superscript T means transpose... | ||
+ | *** And $$\mbox{det}(A)=\sum_{i\mbox{ or }j=0}^{N-1}a_{ij}(-1)^{i+j}M_{ij}$$ for some $$j$$ or $$i$$... | ||
+ | **** And $$M_{ij}$$ is a '''minor''' of $$A$$, specifically the determinant of the matrix that remains if you remove the $$i$$th row and $$j$$th column or, if $$A$$ is a 1x1 matrix, 1 | ||
+ | ***** And $$\mbox{cof(A)}$$ is a matrix where the $$i,j$$ entry $$c_{ij}=(-1)^{i+j}M_{ij}$$ | ||
+ | ** Good news - for this class, you need to know how to calculate inverses of 1x1 and 2x2 matrices only: | ||
+ | :: $$ | ||
+ | \begin{align} | ||
+ | \mbox{inv}([a])&=\frac{1}{a}\\ | ||
+ | \mbox{inv}\left(\begin{bmatrix}a&b\\c&d\end{bmatrix}\right)&=\frac{\begin{bmatrix}d &-b\\-c &a\end{bmatrix}}{ad-bc} | ||
+ | \end{align}$$ | ||
+ | |||
+ | |||
+ | == Lecture 13 - Linear Algebra == | ||
+ | * Chapra 11.2.1 for norms | ||
+ | ** [https://docs.scipy.org/doc/numpy/reference/generated/numpy.linalg.norm.html np.linalg.nrom()] in Python | ||
+ | * Chapra 1.2.2 for condition numbers | ||
+ | ** [https://docs.scipy.org/doc/numpy/reference/generated/numpy.linalg.norm.html np.linalg.cond()] in Python | ||
+ | ** Note: base-10 logarithm of condition number gives number of digits of precision possibly lost due to system geometry and scaling (top of p. 295 in Chapra) | ||
+ | * Converting equations to a matrix system: | ||
+ | ** For a certain circuit, conservation equations learned in upper level classes will yield the following two equations: | ||
+ | :: $$\begin{align} | ||
+ | \frac{v_1-v_s}{R1}+\frac{v_1}{R_2}+\frac{v_1-v_2}{R_3}&=0\\ | ||
+ | \frac{v_2-v_1}{R_3}+\frac{v_2}{R_4}=0 | ||
+ | \end{align}$$ | ||
+ | :* Assuming $$v_s$$ and the $$R_k$$ values are known, to write this as a matrix equation, you need to get $$v_1$$ and $$v_2$$ on the left and everything else on the right: | ||
+ | :: $$\begin{align} | ||
+ | \left(\frac{1}{R_1}+\frac{1}{R_2}+\frac{1}{R_3}\right)v_1+\left(-\frac{1}{R_3}\right)v_2&=\frac{v_s}{R_1}\\ | ||
+ | \left(-\frac{1}{R_3}\right)v_1+\left(\frac{1}{R_3}+\frac{1}{R_4}\right)v_2&=0 | ||
+ | \end{align}$$ | ||
+ | :* Now you can write this as a matrix equation: | ||
+ | $$ | ||
+ | \newcommand{\hmatch}{\vphantom{\frac{1_s}{R_1}}} | ||
+ | \begin{align} | ||
+ | \begin{bmatrix} \frac{1}{R_1}+\frac{1}{R_2}+\frac{1}{R_3} & -\frac{1}{R_3} \\ -\frac{1}{R_3} & \frac{1}{R_3}+\frac{1}{R_4} | ||
+ | \end{bmatrix} | ||
+ | \begin{bmatrix} \hmatch v_1 \\ \hmatch v_2 \end{bmatrix} | ||
+ | &= | ||
+ | \begin{bmatrix} \frac{v_s}{R_1} \\ 0 \end{bmatrix} | ||
+ | \end{align}$$ | ||
+ | |||
+ | == Lecture 14 - Linear Algebra with Parameter Sweeps== | ||
+ | * See [[Python:Linear_Algebra#Sweeping_a_Parameter]] for example code on solving a system of equations when one parameter (either in the coefficient matrix or in the forcing vector or potentially both) | ||
+ | |||
+ | == Lecture 15 - Review == | ||
+ | [[EGR 103/Spring 2020/Test 1]] |
Latest revision as of 17:26, 28 February 2020
Contents
- 1 Lecture 1 - Introduction
- 2 Lecture 2 - Programs and Programming
- 3 Lecture 3 - "Number" Types
- 4 Lecture 4 - More on Types
- 5 Lecture 5 - Printing and Decisions
- 6 Lecture 6 - Decisions
- 7 Lecture 7 - Loops
- 8 Lecture 8 - Iterative Methods
- 9 Lecture 9 - Dictionaries and Loading
- 10 Lecture 10 - Monte Carlo Methods
- 11 Lecture 11 - Binary and Floating Point Numbers
- 12 Lecture 12 - Matrix Operations
- 13 Lecture 13 - Linear Algebra
- 14 Lecture 14 - Linear Algebra with Parameter Sweeps
- 15 Lecture 15 - Review
Lecture 1 - Introduction
- Class web page: EGR 103L; assignments, contact info, readings, etc - see slides on Errata/Notes page
- Sakai page: Sakai 103L page; grades, surveys and tests, some assignment submissions
- Pundit page: EGR 103; reference lists
- CampusWire page: CampusWire 103L page; message board for questions - you need to be in the class and have the access code 6393 to subscribe.
Lecture 2 - Programs and Programming
- Seven steps of programming -
- Watch video on Developing an Algorithm
- Watch video on A Seven Step Approach to Solving Programming Problems
Lecture 3 - "Number" Types
- To play with Python:
- Install it on your machine or a public machine: Download
- Quick tour of Python
- Editing window, variable explorer, and console
- Run icon (F5)
- You are not expected to remember any of the specifics about how Python stores things or works with them yet!
- Python is a "typed" language - variables have types
- We will use eight types:
- Focus of the day: int, float, and array
- Basics today, focus a little later: string, list, tuple
- Focus later: dictionary, set
- int: integers; Python can store these perfectly
- float: floating point numbers - "numbers with decimal points" - Python sometimes has problems storing floating point items exactly
- array
- Requires numpy, usually with
import numpy as np
- Organizational unit for storing rectangular arrays of numbers
- Requires numpy, usually with
- Math with "Number" types works the way you expect
- ** * / // % + -
- Slices allow us to extract information from a collection or change information in mutable collections
- a[0] is the element in a at the start
- a[3] is the element in a three away from the start
- a[-1] is the last element of a
- A string contains an immutable collection of characters
- Using + with strings concatenates strings
- Using * with strings makes a string with the original repeated
- A tuple contains an immutable collection of other types
- Using + with tuples concatenates tuples
- Using * with tuples makes a tuple with the original repeated
- A list contains an immutable collection of other types
- Using + with lists concatenates lists
- Using * with lists makes a list with the original repeated
Lecture 4 - More on Types
- Relational operators can compare "Number" Types and work the way you expect with True or False as an answer
- < <= == >= > !=
- With arrays, either same size or one is a single value; result will be an array of True and False the same size as the array
- More advanced slices:
- a[:] is all the elements in a because what is really happening is:
- a[start:until] where start is the first index and until is just *past* the last index;
- a[3:7] will return a[3] through a[6] in 4-element array
- a[start:until:increment] will skip indices by increment instead of 1
- To go backwards, a[start:until:-increment] will start at an index and then go backwards until getting at or just past until.
- For 2-D arrays, you can index items with either separate row and column indices or indices separated by commas:
- a[2][3] is the same as a[2, 3]
- Only works for arrays!
Lecture 5 - Printing and Decisions
- Creating formatted strings using {} and .format() (format strings, standard format specifiers) -- focus was on using e or f for type, minimumwidth.precision, and possibly a + in front to force printing + for positive numbers.
- Also - Format Specification Mini-Language
Lecture 6 - Decisions
- Rolling dice
# tpir.py from class:
def roll(num=1, sides=6):
print(num, sides)
dice = np.random.randint(1, sides+1, num)
print(dice)
return dice
- Checking rolls:
# tpir.py from class:
import numpy as np
def eval_hand(dice):
sorted_dice = dice*1
sorted_dice.sort()
if sorted_dice[0] == sorted_dice[-1]:
hand_type = 3
tie_value = [sorted_dice[0]]
elif (sorted_dice[0] == sorted_dice[1]-1 and
sorted_dice[0] == sorted_dice[2]-2):
hand_type = 2
tie_value = [sorted_dice[2]]
elif (sorted_dice[1] == sorted_dice[0] or
sorted_dice[1] == sorted_dice[2]):
hand_type = 1
tie_value = [sorted_dice[1]]
if sorted_dice[1] == sorted_dice[0]:
tie_value += [sorted_dice[2]]
else:
tie_value += [sorted_dice[0]]
else:
hand_type = 0
tie_value = sorted_dice[::-1]
return hand_value, tie_value
Lecture 7 - Loops
- The Price Is Right - Clock Game video demonstration
# tpir.py from class:
import numpy as np
def create_price(low=100, high=1500):
return np.random.randint(low, high+1)
def get_guess():
guess = int(input('Guess: '))
return guess
def check_guess(actual, guess):
if actual > guess:
print('Higher!')
elif actual < guess:
print('Lower!')
if __name__ == '__main__':
the_price = create_price()
the_guess = get_guess()
while the_price != the_guess:
check_guess(the_price, the_guess)
the_guess = get_guess()
if the_price==the_guess:
print('You win!!!!!!!')
else:
print('LOOOOOOOOOOOOOOOSER')
- Getting temperatures:
# get_temps.py from class:
T = int(input('Temp: '))
Tlist = []
while T>=0:
Tlist += [T]
print(Tlist)
T = int(input('Temp: '))
Lecture 8 - Iterative Methods
- Taylor series fundamentals
- Maclaurin series approximation for exponential uses Chapra 4.2 to compute terms in an infinite sum.
- so
- Newton Method for finding square roots uses Chapra 4.2 to iteratively solve using a mathematical map. To find \(y\) where \(y=\sqrt{x}\):
\( \begin{align} y_{init}&=1\\ y_{new}&=\frac{y_{old}+\frac{x}{y_{old}}}{2} \end{align} \) - See Python version of Fig. 4.2 and modified version of 4.2 in the Resources section of Sakai page under Chapra Pythonified
Lecture 9 - Dictionaries and Loading
Lecture 10 - Monte Carlo Methods
- From Wikipedia: Monte Carlo method
- See file in "Programs From Class" folder under Resources on Sakai
Lecture 11 - Binary and Floating Point Numbers
- Different number systems convey information in different ways.
- Roman Numerals
- Chinese Numbers
- Binary Numbers
- We went through how to convert between decimal and binary
- Kibibytes et al
- "One billion dollars!" may not mean the same thing to different people: Long and Short Scales
- Floats (specifically double precision floats) are stored with a sign bit, 52 fractional bits, and 11 exponent bits. The exponent bits form a code:
- 0 (or 00000000000): the number is either 0 or a denormal
- 2047 (or 11111111111): the number is either infinite or not-a-number
- Others: the power of 2 for scientific notation is 2**(code-1023)
- The largest number is thus just *under* 2**1024 (ends up being (2-2**-52)**1024\(\approx 1.798\times 10^{308}\).
- The smallest normal number (full precision) is 2**(-1022)\(\approx 2.225\times 10^{-308}\).
- The smallest denormal number (only one significant binary digit) is 2**(-1022)/2**53 or 5e-324.
- When adding or subtracting, Python can only operate on the common significant digits - meaning the smaller number will lose precision.
- (1+1e-16)-1=0 and (1+1e-15)-1=1.1102230246251565e-15
- Avoid intermediate calculations that cause problems: if x=1.7e308,
- (x+x)/x is inf
- x/x + x/x is 2.0
Lecture 12 - Matrix Operations
- 1D arrays are neither rows nor columns - they are 1D!
- 2D arrays have...two dimensions, one of which might be 1
- Dot products as heart of matrix multiplication
- Inner dimensions must match; outer dimensions equal dimensions of result
- Reformatting linear algebra expressions as matrix equations
- Calculating determinants and inverses
- Shortcuts for determinants of 1x1, 2x2 and 3x3 matrices (see class notes for processes)
- $$\begin{align*} \mbox{det}([a])&=a\\ \mbox{det}\left(\begin{bmatrix}a&b\\c&d\end{bmatrix}\right)&=ad-bc\\ \mbox{det}\left(\begin{bmatrix}a&b&c\\d&e&f\\g&h&i\end{bmatrix}\right)&=aei+bfg+cdh-afh-bdi-ceg\\ \end{align*}$$
- Don't believe me? Ask Captain Matrix!
- Inverses of matrices:
- Generally, $$\mbox{inv}(A)=\frac{\mbox{cof}(A)^T}{\mbox{det}(A)}$$ there the superscript T means transpose...
- And $$\mbox{det}(A)=\sum_{i\mbox{ or }j=0}^{N-1}a_{ij}(-1)^{i+j}M_{ij}$$ for some $$j$$ or $$i$$...
- And $$M_{ij}$$ is a minor of $$A$$, specifically the determinant of the matrix that remains if you remove the $$i$$th row and $$j$$th column or, if $$A$$ is a 1x1 matrix, 1
- And $$\mbox{cof(A)}$$ is a matrix where the $$i,j$$ entry $$c_{ij}=(-1)^{i+j}M_{ij}$$
- And $$M_{ij}$$ is a minor of $$A$$, specifically the determinant of the matrix that remains if you remove the $$i$$th row and $$j$$th column or, if $$A$$ is a 1x1 matrix, 1
- And $$\mbox{det}(A)=\sum_{i\mbox{ or }j=0}^{N-1}a_{ij}(-1)^{i+j}M_{ij}$$ for some $$j$$ or $$i$$...
- Good news - for this class, you need to know how to calculate inverses of 1x1 and 2x2 matrices only:
- Generally, $$\mbox{inv}(A)=\frac{\mbox{cof}(A)^T}{\mbox{det}(A)}$$ there the superscript T means transpose...
- $$ \begin{align} \mbox{inv}([a])&=\frac{1}{a}\\ \mbox{inv}\left(\begin{bmatrix}a&b\\c&d\end{bmatrix}\right)&=\frac{\begin{bmatrix}d &-b\\-c &a\end{bmatrix}}{ad-bc} \end{align}$$
Lecture 13 - Linear Algebra
- Chapra 11.2.1 for norms
- np.linalg.nrom() in Python
- Chapra 1.2.2 for condition numbers
- np.linalg.cond() in Python
- Note: base-10 logarithm of condition number gives number of digits of precision possibly lost due to system geometry and scaling (top of p. 295 in Chapra)
- Converting equations to a matrix system:
- For a certain circuit, conservation equations learned in upper level classes will yield the following two equations:
- $$\begin{align} \frac{v_1-v_s}{R1}+\frac{v_1}{R_2}+\frac{v_1-v_2}{R_3}&=0\\ \frac{v_2-v_1}{R_3}+\frac{v_2}{R_4}=0 \end{align}$$
- Assuming $$v_s$$ and the $$R_k$$ values are known, to write this as a matrix equation, you need to get $$v_1$$ and $$v_2$$ on the left and everything else on the right:
- $$\begin{align} \left(\frac{1}{R_1}+\frac{1}{R_2}+\frac{1}{R_3}\right)v_1+\left(-\frac{1}{R_3}\right)v_2&=\frac{v_s}{R_1}\\ \left(-\frac{1}{R_3}\right)v_1+\left(\frac{1}{R_3}+\frac{1}{R_4}\right)v_2&=0 \end{align}$$
- Now you can write this as a matrix equation:
$$ \newcommand{\hmatch}{\vphantom{\frac{1_s}{R_1}}} \begin{align} \begin{bmatrix} \frac{1}{R_1}+\frac{1}{R_2}+\frac{1}{R_3} & -\frac{1}{R_3} \\ -\frac{1}{R_3} & \frac{1}{R_3}+\frac{1}{R_4} \end{bmatrix} \begin{bmatrix} \hmatch v_1 \\ \hmatch v_2 \end{bmatrix} &= \begin{bmatrix} \frac{v_s}{R_1} \\ 0 \end{bmatrix} \end{align}$$
Lecture 14 - Linear Algebra with Parameter Sweeps
- See Python:Linear_Algebra#Sweeping_a_Parameter for example code on solving a system of equations when one parameter (either in the coefficient matrix or in the forcing vector or potentially both)