From: Andrew Lorimer Date: Sat, 7 Jul 2018 04:57:32 +0000 (+1000) Subject: add english, methods, spec notes X-Git-Tag: yr11~90 X-Git-Url: https://git.lorimer.id.au/notes.git/diff_plain/872d16b743107c7b9112e36268963115e885e480?ds=inline add english, methods, spec notes --- diff --git a/english/stasiland-history.md b/english/stasiland-history.md new file mode 100644 index 0000000..2bdfbca --- /dev/null +++ b/english/stasiland-history.md @@ -0,0 +1,49 @@ +# Stasiland - History + +## Cold war + +- 1945 - 1991 +- USA (cap) and USSR (com) dominated after WWII + + +### Communism +- German philosophers Marx & Engels ($\approx$ 1848) +- industrial revolution +- response to class struggles + +#### Key concets of Marxism +- determinism (belief that communism's domination is inevitable) +- stages of history: +- 1. **slave society** +- 2. **feudal** +- 3. **capitalist** - hierarchy +- 4. **socialist** - production is owned collectively +- 5. **communism** - classless utopia +- class consciousness +- dictatorship of the proletariat + +### Origins of the Cold War + +- defeat of Nazi Germany in 1945 - Europe jointly occupied by Soviet Red Army (East), Americans and British (West) +- tension between Stalin (Soviet) and American/British +- 1945 - Winston Churchill warns of "iron curtain" on Europe +- Europe and Berlin split into two halves + +#### Iron curtain +- metaphor for blocks (East and West) +- Yalta conference - Germany divided into four zones +- US gained economic power (commodities of gold & USD) +- Truman Doctrine - US president, challenged communism +- Soviets blocked West Berlin +- 1949 - Federal Republic of Germany (GDR) + +### Berlin + +- East Berlin tightly controlled by state - deprivation of essential goods +- Ulbricht - erected Berlin Wall in $\approx$ 1953 to prevent mass exodus of E. Berlin + +### Fall of the Iron Curtain +- 1985 - Gorbachev's reformist policies - "openness" and "restructuring" +- some Communist ideals approached capitalism +- 1973 - East and West Germany joined UN +- 1990 - reunification diff --git a/methods/circ-functions.md b/methods/circ-functions.md new file mode 100644 index 0000000..d232247 --- /dev/null +++ b/methods/circ-functions.md @@ -0,0 +1,23 @@ +# Circular functions + +## Radians and degrees + +$$1 \thinspace \operatorname{rad}={{180 \operatorname{deg}}\over \pi}$$ + +## Exact values + +## $\sin$ and $\cos$ graphs + +$$f(x)=a \sin(bx-c)+d$$ +$$f(x)=a \cos(bx-c)+d$$ + +where +$a$ is the amplitude +$b$ is the $x$-dilation +$c$ is the $y$-shift + +Period is ${2 \pi} \over b$ +Domain is $\mathbb{R}$ +Range is $[-b+c, b+c]$; + +Graph of $\cos(x)$ starts at $(0,1)$. Graph of $\sin(x)$ starts at $(0,0)$. diff --git a/spec/graphing.md b/spec/graphing.md index 94c5a4a..5d75efc 100644 --- a/spec/graphing.md +++ b/spec/graphing.md @@ -18,27 +18,33 @@ As $\quad x \rightarrow \pm \infty,\quad {-1 \over x}$ - set of points that satisfy a given condition - path traced by a point that moves according to a condition +- graph on CAS - **conics** ### Circular loci +point $P(x,y)$ has a constant distance $r$ from point $C(a,b)$ (centre) + + +$$PC = r$$ + $$(x-a)^2 + (y-b)^2 = r^2$$ -point $P(x,y)$ has a constant distance $r$ from point $C(a,b)$ (centre) + ### Linear loci -$$QP=RP$$ +$$QP = RP $$ $$\sqrt{(x_Q-q_P)^2+(y_Q-y_P)^2} = \sqrt{(x_R-x_P)^2+(y_R-y_P)^2}$$ points $Q$ and $R$ are fixed and have a perpendicular bisector $QR$. Therefore, any point on line $y=mx+c$ is equidistant from $QP$ and $RP$. -Since the bisector of the line joining points $Q$ and $R$ is perpendicular to $QR$: +Since the bisector of the line joining points $Q$ and $R$ is perpendicular to $QR $: -$$m(QR) \times m(RP) = -1$$ +$$m( QR ) \times m( RP ) = -1$$ ### Parabolic loci -$$PD=PF$$ +$$PD = PF $$ $$|y-z|=\sqrt{(x-x_F)^2+(y-y_F)^2}$$ $$(y-z)^2=(x-x_F)^2+(y-y_F)^2$$ @@ -50,6 +56,47 @@ Fixed line $x=z$ is the **directrix** ### Elliptical loci -$$F_1 P + F_2 P =k$$ +Point $P$ moves so that the sum of its distances from two fixed points $F_1$ and $F_2$ is a constant $k$. + +$${F_1 P} + F_2 P =k$$ **Two** foci at $F_1$ and $F_2$ + +Cartesian equation for ellipses: +$${(x-h)^2 \over a^2} + {(y-k)^2 \over b^2} = 1$$ +centered at $(h,k)$. Width is $2a$, height is $2b$. + +### Transformations +$$(x,y) \rightarrow (x \prime, y \prime)$$ + +where $x \prime$ and $y \prime$ are the transformation factors (dilation away from $x$-axis means coefficient of $y$ increases in $y \prime$, and vice versa). + +Transformed equation is the same as initial equation with each term divided by its dilation coefficients (must be in terms of $x\prime$ and $y\prime$). + +e.g. + +$x^2 + y^2 = 1$ is dilated $3$ from $x$, $5$ from $y$. +Transformation rule is $(x\prime,y\prime) = (5x,3y)$ +$x={x\prime \over 5},\quad y={y\prime \over 3}$ + +Equation $x^2 + y^2=1$ becomes + +$${(x\prime)^2 \over 25}+ {(y\prime)^2 \over 9}=1$$ + + +### Hyperbolic loci + +$$|(F_2P - F_1P )| = k$$ + +Cartesian equation for hyperbolas ($a$ and $b$ are dilation factors): +$${(x-h)^2 \over a^2} - {(y-k)^2 \over b^2} = 1$$ + +Asymptotes at $y-k=\pm {b \over a}(x-h$) + +## Parametric equations + +Parametric curve: + +$$x=f(t), \quad y=g(t)$$ + +$t$ is the parameter