VECTORS

VECTORS Name:_______________________________

Partners:____________________________________ Course:________________

Visit the following site and get an understanding of vectors and scalars.

Purpose: To determine
(a) the resultant and equilibrant of two or more vectors
(b) the components of a vector
analytically and to verify the results using a force table and a PC.

Apparatus: force table with pulleys, mass hangers, mass set, string, level, and PC.

Theory: a) analytical method

Let's say two forces F₁(making an angle θ₁with the x-axis) and F₂(making an angle θ₂with the x-axis) are acting on an object. To find the resultant force we will do the following:

Force	X-component	Y-component
F₁	F₁ Cos θ₁	F₁ Sin θ₁
F₂	F₂ Cos θ₂	F₂ Sin θ₂
F₁ + F₂	F_x = F₁ Cos θ₁+ F₂ Cosθ₂	F_y = F₁ Sin θ₁+ F₂ Sin θ₂

Magnitude of the resultant (F_R) is given by; F_R ^2 = F_x ²+ F_y ²

Direction of the resultant, θ_R, measured from the X - axis depends on the signs of Fx and Fy.

When Fx > 0 and Fy >0; θ_R = tan^-1(F_y/F_x).

When the components are negative go the appropriate quadrants and determine θ_R.

The equilibrant is given by:

magnitude = magnitude of the resultant.

direction = θ_E= 180 + θ_R.

Procedure

A) Use of a PC:

1. Click "Short cut to Phys".

2. Type 1(one) and Enter.

3. Type P and put in the magnitude of the first vector and Enter.

4. Put in the angle of the first vector and Enter.

5. Type P and put in the magnitude of the second vector and Enter.

6. Put in the angle of the second vector and Enter.

7. Push Esc for vector data list or continue with third and fourth vectors.

8. Obtain F_R (=R) and θ_R (=A) for the first 4 cases and Fx and Fy for the last case.

9. Type "system" and enter and then type "exit" to get to windows.

B) Analytical Method

Use the analytical method and find the magnitude and the direction of the resultant. Estimate the direction of the equilibrant.

C) Force Table Check

Addition of two vectors:

1) Use a level to make sure the force table is leveled.

2) Mount a pulley on the 0 degree mark and suspend a 50 gram mass hanger. Mount a second pulley on the 90 degree mark and suspend a 100 gram mass (hanger and a 50 gram mass).

3) Set up the equilibrant on the force table and test the system for equilibrium.

4) Remove all the masses from the force table.

5) Mount a pulley on the 20 degree mark and suspend a 50 gram mass. Mount a second pulley on the 120 degree mark and suspend a 250 gram mass.

6) Set up the equilibrant on the force table and test the system for equilibrium.

7) Remove the equilibrant mass.

Addition of three vectors:

1) Mount a pulley on the 300 degree mark and suspend a 300 gram mass (masses 50 gram and 250 gram are already there).

2) Set up the equilibrant on the force table and test the system for equilibrium.

3) Remove all the masses from the force table.

Addition of four vectors:

1) Mount a pulley on the 30 degree mark and suspend a 100 gram mass. Mount a second pulley on the 140 degree mark and suspend a 150 gram mass. Mount a third pulley on the 200 degree mark and suspend a 125 gram mass. Mount a fourth pulley on the 300 degree mark and suspend a 200 gram mass.

2) Set up the equilibrant on the force table and test the system for equilibrium.

3) Remove all the masses from the force table.

Vector resolution:

1) Mount a pulley on the 30 degree mark and suspend a 300 gram mass over it.

2) Find the magnitudes of the components along the 0 degree (X- axis) and 90 degree (Y-axis) directions.

3) Set up the above components as they have been determined. Move the 300 gram mass to, 30 + 180 = 210 degrees, which is the direction of the equilibrant. Test the system for equilibrium.

DATA

Addition	Resultant Vector		Force Table Check
	From computer	Analytical method
50 g @ 0⁰ and 100 g @ 90⁰	F_R=R= θ_R =A=	F_R= θ_R= θ_E=	________
50 g @ 20⁰ and 250 g @ 120⁰	F_R=R= θ_R =A=	F_R= θ_R = θ_E=	________
50 g @ 20⁰ 250 g @ 120⁰ 300 g @ 300⁰	F_R=R= θ_R =A=	F_R= θ_R = θ_E =	________
100 g @ 30⁰ 150 g @ 140⁰ 125 g @ 200⁰ 200 g @ 300⁰	F_R=R= θ_R =A=	F_R= θ_R = θ_E =	_________
Resolution	XXXXXXXXXXXX	XXXXXXXXXXX	XXXXXXXXXXXX
300 g @ 30⁰	F_x= F_y=	F_x= F_y=	_________

Exercise: Use the graphical method to find the magnitude (F_R) & direction (θ_R) of the resultant for the case of addition of four vectors. Here you need to draw a vector diagram, using a protractor and ruler, following the tail-to-tip method, to scale. Show the direction of the vectors and identify F_R & θ_R in the drawing.

F_R= ____________ θ_R = _________________

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