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Test your basic knowledge |
CSET Science: Constants And Equations
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Study First
Subjects
:
cset
,
science
Instructions:
Answer 29 questions in 15 minutes.
If you are not ready to take this test, you can
study here
.
Match each statement with the correct term.
Don't refresh. All questions and answers are randomly picked and ordered every time you load a test.
This is a study tool. The 3 wrong answers for each question are randomly chosen from answers to other questions. So, you might find at times the answers obvious, but you will see it re-enforces your understanding as you take the test each time.
1. Gravitational Force
F=qE; q is the charge - E is the electric field
PE=kq1q2/r
F=qvBsin(a); q = charge (in coulombs); v = velocity of the charge; B = magnetic field; a = angle between the direction of the motion of the charged particle and the direction of the magnetic field
Fg=Gm1m2/r^2
2. Unit of magnetism
Vf = v0 + at - d = d0+ v0t + 1/2at^2 - vf^2=v0^2+2ad - d=(vf+v0)t/2
C=3.08x10^8 m/s
Tesla
V=f*wavelength
3. k (Coulomb's Law)
9x10^9 N m^2/coul^2
Fg=Gm1m2/r^2
PE=kq1q2/r
P=mv
4. Hooke's Law
9x10^9 N m^2/coul^2
F=qE; q is the charge - E is the electric field
Fq=kq1q2/r^2
F=kx; k=spring constant - x = displacement
5. Electric Field
Q=CV; Q = charge in coulombs; C = capacitance in farads; V = voltage
E=kq1/r^2
Tesla
V=f*wavelength
6. Impedence
F=(v+vr)/(v+vs)f0; v = velocity of wave in the medium ; vr = velocity of the receiver relative to the medium -- positive if moving toward the source; vs = velocity of the source relative to the medium -- positive if moving away from the receiver
E=1/2CV^2; C = capacitance; V = voltage
The impedence is given by Z=v( R^2+(?L-1/?C)^2). When ?=?r= 1/vLC - ?L=?C
E=1/2mv^2
7. Ohm's Law
C=3.08x10^8 m/s
V=IR; v = voltage; I = current in amperes (coulombs/sec); R = resistance in Ohms
Tesla
E=1/2CV^2; C = capacitance; V = voltage
8. Power of a lens
V=IR; v = voltage; I = current in amperes (coulombs/sec); R = resistance in Ohms
E=1/2CV^2; C = capacitance; V = voltage
F=kx; k=spring constant - x = displacement
P=1/f
9. Work
W=Fd; W=mgh
F=qE; q is the charge - E is the electric field
9.8 m/s^2
F=(v+vr)/(v+vs)f0; v = velocity of wave in the medium ; vr = velocity of the receiver relative to the medium -- positive if moving toward the source; vs = velocity of the source relative to the medium -- positive if moving away from the receiver
10. Kinematics Equations
F=qE; q is the charge - E is the electric field
9.8 m/s^2
Vf = v0 + at - d = d0+ v0t + 1/2at^2 - vf^2=v0^2+2ad - d=(vf+v0)t/2
F=qvBsin(a); q = charge (in coulombs); v = velocity of the charge; B = magnetic field; a = angle between the direction of the motion of the charged particle and the direction of the magnetic field
11. Potential energy of two charges
V=IR; v = voltage; I = current in amperes (coulombs/sec); R = resistance in Ohms
F=qvBsin(a); q = charge (in coulombs); v = velocity of the charge; B = magnetic field; a = angle between the direction of the motion of the charged particle and the direction of the magnetic field
Graph Hooke's law; area under graph= work = 1/2kx^2
PE=kq1q2/r
12. g
9.8 m/s^2
F=(v+vr)/(v+vs)f0; v = velocity of wave in the medium ; vr = velocity of the receiver relative to the medium -- positive if moving toward the source; vs = velocity of the source relative to the medium -- positive if moving away from the receiver
Fg=Gm1m2/r^2
6.67x10^-11 N m^2/kg^2
13. Energy stored in a capacitor
9x10^9 N m^2/coul^2
Fc = mv^2/r
E=1/2CV^2; C = capacitance; V = voltage
Graph Hooke's law; area under graph= work = 1/2kx^2
14. Power
The impedence is given by Z=v( R^2+(?L-1/?C)^2). When ?=?r= 1/vLC - ?L=?C
P=IV = I^2R = V^2/R; P = power in watts (joule/sec)
P=1/f
9.8 m/s^2
15. Capacitance
F=kx; k=spring constant - x = displacement
Q=CV; Q = charge in coulombs; C = capacitance in farads; V = voltage
E=1/2CV^2; C = capacitance; V = voltage
F(delta)t=change in motion resulting in the application of a force for a given amount of time
16. Coulomb's Law
V=IR; v = voltage; I = current in amperes (coulombs/sec); R = resistance in Ohms
E=1/2mv^2
E=1/2CV^2; C = capacitance; V = voltage
Fq=kq1q2/r^2
17. Force on a charged particle in an electric field
C=3.08x10^8 m/s
Fq=kq1q2/r^2
F=qE; q is the charge - E is the electric field
P=IV = I^2R = V^2/R; P = power in watts (joule/sec)
18. Snell's Law
V=IR; v = voltage; I = current in amperes (coulombs/sec); R = resistance in Ohms
A = v^2/r =Fc/m
Sin(theta1)/sin(theta2)=v1/v2=n1/n2
F(delta)t=change in motion resulting in the application of a force for a given amount of time
19. Force on a moving charge in a magnetic field
F=qvBsin(a); q = charge (in coulombs); v = velocity of the charge; B = magnetic field; a = angle between the direction of the motion of the charged particle and the direction of the magnetic field
F(delta)t=change in motion resulting in the application of a force for a given amount of time
P=1/f
A = v^2/r =Fc/m
20. Doppler Effect
Fg=Gm1m2/r^2
F=(v+vr)/(v+vs)f0; v = velocity of wave in the medium ; vr = velocity of the receiver relative to the medium -- positive if moving toward the source; vs = velocity of the source relative to the medium -- positive if moving away from the receiver
Tesla
P=IV = I^2R = V^2/R; P = power in watts (joule/sec)
21. Centripetal Force
F(delta)t=change in motion resulting in the application of a force for a given amount of time
Fc = mv^2/r
V=f*wavelength
The impedence is given by Z=v( R^2+(?L-1/?C)^2). When ?=?r= 1/vLC - ?L=?C
22. Impulse
F(delta)t=change in motion resulting in the application of a force for a given amount of time
Q=CV; Q = charge in coulombs; C = capacitance in farads; V = voltage
Sin(theta1)/sin(theta2)=v1/v2=n1/n2
P=IV = I^2R = V^2/R; P = power in watts (joule/sec)
23. Speed of light
C=3.08x10^8 m/s
Sin(theta1)/sin(theta2)=v1/v2=n1/n2
E=1/2CV^2; C = capacitance; V = voltage
9x10^9 N m^2/coul^2
24. Momentum
P=mv
F=qvBsin(a); q = charge (in coulombs); v = velocity of the charge; B = magnetic field; a = angle between the direction of the motion of the charged particle and the direction of the magnetic field
P=1/f
A = v^2/r =Fc/m
25. G (gravitational force)
6.67x10^-11 N m^2/kg^2
Vf = v0 + at - d = d0+ v0t + 1/2at^2 - vf^2=v0^2+2ad - d=(vf+v0)t/2
PE=kq1q2/r
W=Fd; W=mgh
26. Work done by spring displacement
27. Kinetic Energy
E=1/2mv^2
W=Fd; W=mgh
Fq=kq1q2/r^2
Q=CV; Q = charge in coulombs; C = capacitance in farads; V = voltage
28. Circular Acceleration
A = v^2/r =Fc/m
The impedence is given by Z=v( R^2+(?L-1/?C)^2). When ?=?r= 1/vLC - ?L=?C
Q=CV; Q = charge in coulombs; C = capacitance in farads; V = voltage
F=qE; q is the charge - E is the electric field
29. Wave characteristics
6.67x10^-11 N m^2/kg^2
E=kq1/r^2
V=f*wavelength
C=3.08x10^8 m/s