From: W. Trevor King Date: Wed, 2 May 2012 20:14:21 +0000 (-0400) Subject: Update Giancoli v6 to use Circ.asy v0.2. X-Git-Url: http://git.tremily.us/?a=commitdiff_plain;h=b7dc155f6a92c1311914c98bfdaf4aa520375ea1;p=course.git Update Giancoli v6 to use Circ.asy v0.2. --- diff --git a/latex/problems/Giancoli_6/problem17.40.tex b/latex/problems/Giancoli_6/problem17.40.tex index 3a579a6..20975e5 100644 --- a/latex/problems/Giancoli_6/problem17.40.tex +++ b/latex/problems/Giancoli_6/problem17.40.tex @@ -20,19 +20,19 @@ real u = 1cm; real dx = u; real dy = 1.5u; -TwoTerminal bat = battery("$V$"); -TwoTerminal c1 = capacitor("$C_1$", draw=false); -centerto(bat, c1, dy); c1.draw(); -wire(bat.end, c1.end, rlsq, dx/2); -wire(bat.beg, c1.beg, rlsq, -dx/2); -label("(a)", bat.mid + (0, -dy/2)); +MultiTerminal bat = battery("$V$"); +MultiTerminal c1 = capacitor("$C_1$", draw=false); +two_terminal_centerto(bat, c1, dy); c1.draw(); +wire(bat.terminal[1], c1.terminal[1], rlsq, dx/2); +wire(bat.terminal[0], c1.terminal[0], rlsq, -dx/2); +label("(a)", bat.center + (0, -dy/2)); c1.shift(3*dx); c1.draw(); -TwoTerminal c2 = capacitor("$C_2$", draw=false); -centerto(c1, c2, -dy); c2.draw(); -wire(c2.end, c1.end, rlsq, dx/2); -wire(c2.beg, c1.beg, rlsq, -dx/2); -label("(b)", c2.mid + (0, -dy/2)); +MultiTerminal c2 = capacitor("$C_2$", draw=false); +two_terminal_centerto(c1, c2, -dy); c2.draw(); +wire(c2.terminal[1], c1.terminal[1], rlsq, dx/2); +wire(c2.terminal[0], c1.terminal[0], rlsq, -dx/2); +label("(b)", c2.center + (0, -dy/2)); \end{asy} \end{center} \end{problem*} @@ -46,25 +46,25 @@ real u = 1cm; real dx = u; real dy = 1.5u; -TwoTerminal bat = battery("$V$"); -TwoTerminal c1 = capacitor("$C_1$", draw=false); -centerto(bat, c1, dy); c1.draw(); -wire(bat.end, c1.end, rlsq, dx/2); -wire(bat.beg, c1.beg, rlsq, -dx/2); -label("(a)", bat.mid + (0, -dy/2)); -label("$Q_{1a}$", c1.end, NE); -label("$-Q_{1a}$", c1.beg, NW); +MultiTerminal bat = battery("$V$"); +MultiTerminal c1 = capacitor("$C_1$", draw=false); +two_terminal_centerto(bat, c1, dy); c1.draw(); +wire(bat.terminal[1], c1.terminal[1], rlsq, dx/2); +wire(bat.terminal[0], c1.terminal[0], rlsq, -dx/2); +label("(a)", bat.center + (0, -dy/2)); +label("$Q_{1a}$", c1.terminal[1], NE); +label("$-Q_{1a}$", c1.terminal[0], NW); c1.shift(3*dx); c1.draw(); -TwoTerminal c2 = capacitor("$C_2$", draw=false); -centerto(c1, c2, -dy); c2.draw(); -wire(c2.end, c1.end, rlsq, dx/2); -wire(c2.beg, c1.beg, rlsq, -dx/2); -label("(b)", c2.mid + (0, -dy/2)); -label("$Q_{1b}$", c1.end, NE); -label("$-Q_{1b}$", c1.beg, NW); -label("$Q_{2b}$", c2.end, SE); -label("$-Q_{2b}$", c2.beg, SW); +MultiTerminal c2 = capacitor("$C_2$", draw=false); +two_terminal_centerto(c1, c2, -dy); c2.draw(); +wire(c2.terminal[1], c1.terminal[1], rlsq, dx/2); +wire(c2.terminal[0], c1.terminal[0], rlsq, -dx/2); +label("(b)", c2.center + (0, -dy/2)); +label("$Q_{1b}$", c1.terminal[1], NE); +label("$-Q_{1b}$", c1.terminal[0], NW); +label("$Q_{2b}$", c2.terminal[1], SE); +label("$-Q_{2b}$", c2.terminal[0], SW); \end{asy} \end{center} diff --git a/latex/problems/Giancoli_6/problem19.24.tex b/latex/problems/Giancoli_6/problem19.24.tex index 1dc6d58..5791ebf 100644 --- a/latex/problems/Giancoli_6/problem19.24.tex +++ b/latex/problems/Giancoli_6/problem19.24.tex @@ -4,17 +4,18 @@ Determine the terminal voltage of each battery in Fig.~19-44. \begin{asy} import Circ; real u = 3cm; - TwoTerminal ra = resistor((0,0), ang=0, "$r_1 = 1.0\U{\Ohm}$", ""); - TwoTerminal Ba = source( - ra.end, ang=0, type=DC, "", "$\mathcal{E}_1 = 12\U{V}$"); - TwoTerminal rb = resistor(ra.beg+(0,-u), ang=0, "$r_2 = 2.0\U{\Ohm}$", ""); - TwoTerminal Bb = source( - rb.end, ang=0, type=DC, "", "$\mathcal{E}_2 = 18\U{V}$"); - TwoTerminal R = resistor( - Bb.end+(0.5u,0.25u), ang=90, "", "$R = 6.6\U{\Ohm}$"); - wire(rb.beg, ra.beg, rlsq, dist=-24pt); - wire(Bb.end, R.beg, rlsq); - wire(Ba.end, R.end, rlsq); + MultiTerminal ra = resistor(Label("$r_1 = 1.0\U{\Ohm}$", align=S)); + MultiTerminal Ba = source( + ra.terminal[1], type=DC, label="$\mathcal{E}_1 = 12\U{V}$"); + MultiTerminal rb = resistor(ra.terminal[0]+(0,-u), + Label("$r_2 = 2.0\U{\Ohm}$", align=S)); + MultiTerminal Bb = source( + rb.terminal[1], type=DC, label="$\mathcal{E}_2 = 18\U{V}$"); + MultiTerminal R = resistor( + Bb.terminal[1]+(0.5u,0.25u), dir=90, label="$R = 6.6\U{\Ohm}$"); + wire(rb.terminal[0], ra.terminal[0], rlsq, dist=-24pt); + wire(Bb.terminal[1], R.terminal[0], rlsq); + wire(Ba.terminal[1], R.terminal[1], rlsq); \end{asy} \end{center} \end{problem*} diff --git a/latex/problems/Giancoli_6/problem19.31.tex b/latex/problems/Giancoli_6/problem19.31.tex index 5a6024b..638cc1e 100644 --- a/latex/problems/Giancoli_6/problem19.31.tex +++ b/latex/problems/Giancoli_6/problem19.31.tex @@ -7,18 +7,22 @@ Calculate the currents in each resistor of Fig.~19-49. \begin{asy} import Circ; real u = 3cm; -TwoTerminal Bc = source((0,0), ang=90, type=DC, "", "$3.0\U{V}$"); -TwoTerminal Rcb = resistor(Bc.beg, ang=-90, "$10\U{\Ohm}$", ""); -TwoTerminal Rca = resistor(Bc.end, ang=180, "", "$2\U{\Ohm}$"); -pair Jtop = Rca.end, Jbot = (Jtop.x,Rcb.end.y); -TwoTerminal Rb = resistor(Jtop, ang=-90, "$6\U{\Ohm}$", ""); -TwoTerminal Ba = source(Jtop, ang=180, type=DC, "", "$6.0\U{V}$"); -TwoTerminal Rab = resistor(Jbot, ang=180, "$8\U{\Ohm}$", ""); -TwoTerminal Raa = resistor(Rab.end, ang=90, "$12\U{\Ohm}$", ""); -wire(Ba.end, Raa.end, rlsq); -wire(Rab.beg, Jbot, nsq); -wire(Jbot, Rb.end, nsq); -wire(Jbot, Rcb.end, rlsq); +MultiTerminal Bc = source(dir=90, type=DC, value="$3.0\U{V}$"); +MultiTerminal Rcb = resistor(Bc.terminal[0], dir=-90, + value=Label("$10\U{\Ohm}$", align=E)); +MultiTerminal Rca = resistor(Bc.terminal[1], dir=180, value="$2\U{\Ohm}$"); +pair Jtop = Rca.terminal[1], Jbot = (Jtop.x,Rcb.terminal[1].y); +MultiTerminal Rb = resistor(Jtop, dir=-90, + value=Label("$6\U{\Ohm}$", align=E)); +MultiTerminal Ba = source(Jtop, dir=180, type=DC, value="$6.0\U{V}$"); +MultiTerminal Rab = resistor(Jbot, dir=180, + value=Label("$8\U{\Ohm}$", align=S)); +MultiTerminal Raa = resistor(Rab.terminal[1], dir=90, + value=Label("$12\U{\Ohm}$", align=W)); +wire(Ba.terminal[1], Raa.terminal[1], rlsq); +wire(Rab.terminal[0], Jbot, nsq); +wire(Jbot, Rb.terminal[1], nsq); +wire(Jbot, Rcb.terminal[1], rlsq); \end{asy} \end{center} \end{nosolution} @@ -27,22 +31,26 @@ wire(Jbot, Rcb.end, rlsq); \begin{center} \begin{asy} import Circ; -TwoTerminal Bc = source((0,0), ang=90, type=DC, "", "$3.0\U{V}$"); -TwoTerminal Rcb = resistor(Bc.beg, ang=-90, "$10\U{\Ohm}$", ""); -TwoTerminal Rca = resistor(Bc.end, ang=180, "", "$2\U{\Ohm}$"); -pair Jtop = Rca.end, Jbot = (Jtop.x,Rcb.end.y); -TwoTerminal Ic = current((Jbot+Rcb.end)/2, "", "$I_3$"); -TwoTerminal Rb = resistor(Jtop, ang=-90, "$6\U{\Ohm}$", ""); -TwoTerminal Ib = current(Rb.end, ang=-90, "", "$I_2$"); -TwoTerminal Ba = source(Jtop, ang=180, type=DC, "", "$6.0\U{V}$"); -TwoTerminal Ia = current(Ba.end, ang=180, "$I_1$", ""); -TwoTerminal Rab = resistor(Jbot, ang=180, "$8\U{\Ohm}$", ""); -TwoTerminal Raa = resistor(Rab.end, ang=90, "$12\U{\Ohm}$", ""); -wire(Ia.end, Raa.end, rlsq); -wire(Jbot, Ib.end, nsq); -wire(Jbot, Ic.beg, nsq); -wire(Ib.end, Rb.end, nsq); -wire(Ic.end, Rcb.end, rlsq); +MultiTerminal Bc = source(dir=90, type=DC, value="$3.0\U{V}$"); +MultiTerminal Rcb = resistor(Bc.terminal[0], dir=-90, + value=Label("$10\U{\Ohm}$", align=E)); +MultiTerminal Rca = resistor(Bc.terminal[1], dir=180, value="$2\U{\Ohm}$"); +pair Jtop = Rca.terminal[1], Jbot = (Jtop.x,Rcb.terminal[1].y); +MultiTerminal Ic = current((Jbot+Rcb.terminal[1])/2, Label("$I_3$", align=S)); +MultiTerminal Rb = resistor(Jtop, dir=-90, + value=Label("$6\U{\Ohm}$", align=E)); +MultiTerminal Ib = current(Rb.terminal[1], dir=-90, "$I_2$"); +MultiTerminal Ba = source(Jtop, dir=180, type=DC, value="$6.0\U{V}$"); +MultiTerminal Ia = current(Ba.terminal[1], dir=180, "$I_1$"); +MultiTerminal Rab = resistor(Jbot, dir=180, + value=Label("$8\U{\Ohm}$", align=S)); +MultiTerminal Raa = resistor(Rab.terminal[1], dir=90, + value=Label("$12\U{\Ohm}$", align=W)); +wire(Ia.terminal[1], Raa.terminal[1], rlsq); +wire(Jbot, Ib.terminal[1], nsq); +wire(Jbot, Ic.terminal[0], nsq); +wire(Ib.terminal[1], Rb.terminal[1], nsq); +wire(Ic.terminal[1], Rcb.terminal[1], rlsq); dot("a", Jbot, S); \end{asy} \end{center} diff --git a/latex/problems/Giancoli_6/problem19.58.tex b/latex/problems/Giancoli_6/problem19.58.tex index 6a3ec24..9f136d1 100644 --- a/latex/problems/Giancoli_6/problem19.58.tex +++ b/latex/problems/Giancoli_6/problem19.58.tex @@ -13,16 +13,18 @@ The original situation looks like \begin{asy} import Circ; real u = 0.5cm; -TwoTerminal B = source((0,0), ang=90, type=DC, "$45\U{V}$", "$V$"); -pair a = B.end+(0,u); -pair b = B.beg-(0,u); -TwoTerminal Ra = resistor(a, "$38\U{k\Ohm}$", "$R_1$"); -TwoTerminal Rb = resistor(Ra.end, "$27\U{k\Ohm}$", "$R_2$"); -TwoTerminal I = current((Rb.end.x, (a.y+b.y)/2), ang=-90, "", "$I$"); -wire(Rb.end, I.beg, nsq); -wire(I.end, b, udsq); -wire(b, B.beg, nsq); -wire(a, B.end, nsq); +MultiTerminal B = source(dir=90, type=DC, label="$V$", value="$45\U{V}$"); +pair a = B.terminal[1]+(0,u); +pair b = B.terminal[0]-(0,u); +MultiTerminal Ra = resistor(a, label="$R_1$", value="$38\U{k\Ohm}$"); +MultiTerminal Rb = resistor(Ra.terminal[1], label="$R_2$", + value="$27\U{k\Ohm}$"); +MultiTerminal I = current((Rb.terminal[1].x, (a.y+b.y)/2), dir=-90, + value="$I$"); +wire(Rb.terminal[1], I.terminal[0], nsq); +wire(I.terminal[1], b, udsq); +wire(b, B.terminal[0], nsq); +wire(a, B.terminal[1], nsq); \end{asy} \end{center} Using Kirchhoff's loop rule @@ -42,21 +44,24 @@ With the voltmeter across $R_1$ we have \begin{asy} import Circ; real u = 0.5cm; -TwoTerminal B = source((0,0), ang=90, type=DC, "$45\U{V}$", "$V$"); -pair a = B.end+(0,u); -pair b = B.beg-(0,u); -TwoTerminal Ra = resistor(a, "$38\U{k\Ohm}$", "$R_1$"); -TwoTerminal Ia = current(Ra.end, "", "$I_1$"); -TwoTerminal Rv = resistor(a+(0,4u), "$95\U{k\Ohm}$", "$R_v$"); -TwoTerminal Iv = current(Rv.end, "", "$I_v$"); -TwoTerminal Rb = resistor(Ia.end, "$27\U{k\Ohm}$", "$R_2$"); -TwoTerminal I = current((Rb.end.x, (a.y+b.y)/2), ang=-90, "", "$I_T$"); -wire(Rb.end, I.beg, nsq); -wire(I.end, b, udsq); -wire(b, B.beg, nsq); -wire(a, B.end, nsq); -wire(a, Rv.beg, nsq); -wire(Iv.end, Ia.end, rlsq); +MultiTerminal B = source((0,0), dir=90, type=DC, label="$V$", + value="$45\U{V}$"); +pair a = B.terminal[1]+(0,u); +pair b = B.terminal[0]-(0,u); +MultiTerminal Ra = resistor(a, label="$R_1$", value="$38\U{k\Ohm}$"); +MultiTerminal Ia = current(Ra.terminal[1], label="$I_1$"); +MultiTerminal Rv = resistor(a+(0,4u), label="$R_v$", value="$95\U{k\Ohm}$"); +MultiTerminal Iv = current(Rv.terminal[1], label="$I_v$"); +MultiTerminal Rb = resistor(Ia.terminal[1], label="$R_2$", + value="$27\U{k\Ohm}$"); +MultiTerminal I = current((Rb.terminal[1].x, (a.y+b.y)/2), dir=-90, + label="$I_T$"); +wire(Rb.terminal[1], I.terminal[0], nsq); +wire(I.terminal[1], b, udsq); +wire(b, B.terminal[0], nsq); +wire(a, B.terminal[1], nsq); +wire(a, Rv.terminal[0], nsq); +wire(Iv.terminal[1], Ia.terminal[1], rlsq); \end{asy} \end{center} Using our formula for resistors in parallel, we can bundle $R_v$ and $R_1$ into a single resistor $R_1'$, where diff --git a/latex/problems/Giancoli_6/question19.13.tex b/latex/problems/Giancoli_6/question19.13.tex index feae864..614b0d8 100644 --- a/latex/problems/Giancoli_6/question19.13.tex +++ b/latex/problems/Giancoli_6/question19.13.tex @@ -8,13 +8,14 @@ battery. \begin{asy} import Circ; real u = 1cm; - TwoTerminal B = source((0,0), DC, 0, "", "$V$"); - TwoTerminal r = resistor(B.end, normal, 0, "", "$r$"); - TwoTerminal R = resistor((0,u), normal, 0, "$R$", ""); - TwoTerminal I = current((r.end.x, R.end.y), 180, "", "$I$"); - wire(B.beg, R.beg, udsq); - wire(r.end, I.beg, udsq); - wire(I.end, R.end, nsq); + MultiTerminal B = source(type=DC, label="$V$"); + MultiTerminal r = resistor(B.terminal[1], type=normal, label="$r$"); + MultiTerminal R = resistor((0,u), type=normal, label="$R$"); + MultiTerminal I = current((r.terminal[1].x, R.terminal[1].y), dir=180, + label=Label("$I$", align=N)); + wire(B.terminal[0], R.terminal[0], udsq); + wire(r.terminal[1], I.terminal[0], udsq); + wire(I.terminal[1], R.terminal[1], nsq); \end{asy} \end{center} Make a circuit using a known resistance $R$ to connect the two