Question 1164371
The ends X and Y of an inextensible string 27m long are fixed at two points on the same horizontal line which are {{{20m}}} apart.
A particle of mass 7.5kg is suspended from a point P on the string 12m from X.
  
As it is an inextensible string, it will not stretch and its total length will always be {{{27m}}} . If the point P is at {{{12m}}} from point X, point P will be at {{{27m-12m=15m}}} from point Y.
 
a) illustrate this information in a diagram
The diagram will show the triangle, XYZ with the length shown as numbers without the units,
as it is understood that they the lengths are in meters.
For easy reference, the height {{{green(h)}}} with respect to base XY will be shown, as well as the length of {{{green(d)}}} of the projection of segment XP onto XY.
{{{drawing(400,200,-2.5,22.5,11,-1.5,
green(triangle(5.475,0,5.475,0,5.475,6.15)),
green(rectangle(5.475,0,5.175,0.3)),
triangle(0,0,20,0,5.475,6.15),locate(5.6,3,green(h)),
locate(2.6,0,green(d)),locate(9.4,-0.9,20),
locate(1.8,3,12),locate(12.8,3,15),
locate(-0.6,-0.4,X),locate(20.1,-0.4,Y),locate(5.6,6,P)
)}}}
 
b) calculate, correct to two decimal places angle YXP and angle XYP
The angles in question are those at X and Y. For short, those angles and their measures will be referred to as {{{X}}} and {{{Y}}} .
The measuring units are not specified, but will be calculated in degrees.
A first step would be calculating trigonometric functions of the angles, such as {{{cos(X)}}} and {{{cos(Y)}}} , from the known lengths.

 
To calculate {{{X}}} and {{{Y}}} a student who has been taught how to solve triangles that are not necessarily right triangles could use the law of cosines to calculate {{{cos(X)}}} and {{{cos(Y)}}},
unless a different calculation is expected.
Law of cosines says that in a triangle ABC, with vertices A, B, and C opposite sides a, b, and c, respectively, the side and angle measures are related by
{{{a^2=b^2+c^2-2bc*cos(A)}}} .
Applied to angle {{{X}}} , you get
{{{15^2=20^2+12^2-2*20*12*cos(X)}}}-->{{{225=400+144-480*cos(X)}}}-->{{{225-400-144+480*cos(X)=0}}}->{{{-319+480*cos(X)=0}}}->{{{cos(X)=319/480=0.664583}}}--> {{{X=highlight(48.35^o)}}}
Applied to angle {{{Y}}} , you get
{{{12^2=20^2+15^2-2*20*15*cos(Y)}}}-->{{{144=400+225-600*cos(Y)}}}-->{{{144-400-225+600*cos(Y)=0}}}-->{{{-481+600*cos(Y)=0}}}->{{{cos(Y)=481/600=0.801667}}}--> {{{Y=highlight(36.71^o)}}}
 
For students who know Heron's (or Hero's) formula, they can calculate the area {{{A}}} of triangle XYZ, and from that and the length of side XY, calculate {{{green(h)}}} , and from there calculate {{{sin(X)}}} and {{{sin(Y)}}} to find {{{X}}} and {{{Y}}} .
Heron's (or Hero's) formula says that {{{A=sqrt(s(s-a)(s-b)(s-c))}}} where a, b, and c are the lengths of the triangle sides, and {{{s=(a+b+c)/2}}} is the semiperimeter.
In this case {{{s=(20+15+12)/2=47/2=23.5}}}
{{{A=sqrt(23.5(23.5-20)(23.5-15)(23.5-12)) =sqrt(23.5*3.5*11.5*8.5)=sqrt(8039.9375)=89.6657}}}
As the area of a triangle is {{{base*height/2}}} ,
{{{89.6657=20*green(h)/2}}}--> {{{green(h)=V*2/20=8.96657
{{{sin(X)=green(h)/12=0.747214}}}-->{{{X=highlight(48.35^o)}}}
{{{sin(Y)=green(h)/15=0.597771}}}-->{{{Y=highlight(36.71^o)}}}
 
Another option is to consider the two right triangles formed by splitting triangle XYZ along the altitude labeled as {{{green(h)}}} , using the Pythagorean theorem to calculate {{{green(d)}}} , and calculating {{{cos(X)}}} and {{{cos(Y)}}} as trigonometric ratios.
The Pythagorean theorem only applies to right triangles. If A is the right angle opposite hypotenuse of length a, and the length of the legs of the right triangle are b and c,
then {{{a^2=b^2+c^2}}} .
Applying it to the right triangle with side lengths (in meters) {{{12}}}, {{{green(d)}}} and {{{green(h)}}}, we get
{{{12^2=green(d)^2+green(h)^2}}}-->{{{highlight(144-green(d)^2)=green(h)^2}}}
Applying it to the other right triangle, the one with side lengths (in meters) {{{15}}}, {{{20-green(d)}}} and {{{green(h)}}}, we get
{{{15^2=(20-green(d))^2+green(h)^2}}}-->{{{225=400-2*20*green(d)^2+green(h)^2}}}-->{{{225=400-40green(d)^2+green(h)^2}}}-->{{{highlight(225-400+40green(d)-green(d)^2)=green(h)^2}}}
As the two highlighted expressions are equal to {{{green(h)^2}}} ,  we can write
{{{144-green(d)^2=225-400+40green(d)-green(d)^2)}}}-->{{{144=225-400+40green(d)}}}-->{{{144-225+400=40green(d)}}}-->{{{319=40green(d)}}}-->{{{green(d)=319/40=7.975}}}
{{{cos(X)=green(d)/12=7.975/12=0.664583}}}
{{{cos(Y)=(20-green(d))/15=(20-7.975)/15=12.025/15=0.801667}}}

c) find, correct to the nearest hundredth, the magnitudes of the tensions in the string. [Take g=10 m/s2]
The weight of an object of mass {{{m}}} in a location with a gravitational acceleration {{{g}}} is a force {{{W=m*g}}} .
With the mass in kg and the acceleration in {{{"m /"}}}{{{s^2}}} , the resulting product will be the force in newtons, abbreviated {{{N}}} .
If we use {{{g=10}}}{{{"m /"}}}{{{s^2}}} , the weight calculates as {{{7.5*10N=75N}}}
The tensions on both sides of the string are the forces pulling to balance the weight of
the 7.5kg particle. The three forces can be considered vectors that add up to zero force, meaning no net force on the particle, and no motion of the particle.
I’ll update the diagram from above with the proper angles, adding the three forces. I will call the tension to the left {{{red(L)}}} and the tension to the right {{{red(R)}}} .
I will use the same names to represent the numeric value of their magnitudes in newtons, without having to write the units at every step.

{{{drawing(400,240,-2.5,22.5,13.5,-1.5,
green(triangle(7.975,0, 7.975,0, 7.975,8.967)),
green(rectangle(7.975,0, 7.675,0.3)),
triangle(0,0,20,0,7.975,8.967),
green(arc(0,0,2,2,-48,0)),green(arc(0,0,2.5,2.5,-48,0)),
green(arc(8,9,2,2,132,180)),green(arc(8,9,2.5,2.5,132,180)),
green(arc(20,0,2,2,180,216.7)),green(arc(8,9,2,2,0,36.7)),
locate(9.4,-0.9,20),locate(3.2,4.5,12),locate(13.8,4.5,15),
locate(-0.6,-0.4,X),locate(20.1,-0.4,Y),locate(7.3,9,P),
green(rectangle(8,9,6,6.74)),green(rectangle(8,9,10,7.5)),
green(rectangle(6.3,8.7,6,9)),green(rectangle(9.7,8.7,10,9)),
blue(arrow(8,9,8,12.75)),
red(line(8,9,6,6.74)),red(arrow(8,9,6,6.74)),
red(arrow(8,9,10,7.5)),red(line(8,9,10,7.5)),
locate(8.4,12.25,blue(W)),locate(10.2,7.5,red(R)),locate(5.5,7.1,red(L))
)}}}
A trick that works for many vector problems in Physics class is decomposing some them into a horizontal component and a vertical component. It works in this case.
To visualize horizontal and vertical component I drew right triangles that form a rectangular "cages" around {{{red(L)}}} and {{{red(R)}}} >
The magnitude of the horizontal component of a vector is the magnitude of the vector times the cosine of the smaller angle it forms with the horizontal.
The magnitude of the vertical component of a vector is the magnitude of the vector times the sine of the smaller angle it forms with the vertical.
I marked those angles with little green arcs showing that their measures are {{{X}}} and {{{Y}}} .
For the vectors {{{red(L)}}} , {{{red(R)}}} , and {{{blue(W)}}} to add to zero,
the vertical components of {{{red(L)}}} , {{{red(R)}}} must add to {{{blue(W)}}}  ,
and the horizontal components of {{{red(L)}}} and {{{red(R)}}} must add to zero.
Those horizontal components point left and right, so their magnitudes must be equal. That means {{{red(L)*cos(X)=red(R)*cos(Y)}}}-->{{{red(L)=red(R)*cos(Y)/cos(X)}}}-->{{{red(L)=red(R)*0.801667/0.664583=1.20627red(R)}}}
The magnitude of the vertical components adds to {{{blue(W)=75}}} , so
{{{red(L)*sin(X)+red(R)*sin(Y)=75}}}
{{{red(L)*0.74721+red(R)*0.59777=75}}}
{{{1.20627red(R)*0.74721+red(R)*0.59777=75}}}
{{{(1.20627*0.74721+0.5977)*red(R)=75}}}-->{{{1.49911*red(R)=75}}}-->{{{red(R)=75/1.49911=highlight(50.0298)}}}
{{{red(L)=1.20627red(R)=1.20627*50.0298=highlight(60.3494)}}}
I carried more than enough decimal places through the calculations,
but as the values for the mass an for g are given with just 2 significant figures,
I would report as results that the magnitudes of the tensions are
{{{red(L)=highlight(60N)}}} and {{{red(R)=highlight(50N)}}} , with just 2 significant figures.