Newton’s Laws of Motion
Newton’s Laws of Motion

... changes in its state of motion The First Law states that all objects have inertia. The more mass an object has, the more inertia it has (and the harder it is to change its motion). So, which has more inertia? A bowling ball or a baseball? ...
Week 9 Wednesday
Week 9 Wednesday

Sample_Final-Exam_test_SOLUTION_PHYSICS_211
Sample_Final-Exam_test_SOLUTION_PHYSICS_211

... A 1.0 Kg block at rest on a horizontal frictionless surface is 1.0 Kg 2.0 Kg 4.0 m/s connected to an un-stretched spring (k= 200 N/m) whose other end is fixed (see figure). A 2.0 Kg block moving at 4 m/s collides with the 1.0 Kg block. 7A If the two blocks stick together after the one dimensional co ...
Ch. 8. Energy
Ch. 8. Energy

... 21. Define mass, weight & volume. What are their units. Refer to your textbook. 22. Would an object of mass 20 kg have greater weight on the Moon, Earth or Jupiter? Jupiter, as it has the greatest value of g. It would weigh the least on the Moon. 23. If an object weighs 400 N, what is its mass ? Mas ...
Hooke`s Law and Simple Harmonic Motion Name
Hooke`s Law and Simple Harmonic Motion Name

Newton and Leibniz – Absolute and Relative Motion
Newton and Leibniz – Absolute and Relative Motion

EGR280_Mechanics_7_Friction
EGR280_Mechanics_7_Friction

chapter 11
chapter 11

... After you pick up a spare, your bowling ball rolls without slipping back toward the ball rack with a linear speed of 2.85 m/s. To reach the rack, the ball rolls up a ramp that rises through a vertical distance of 0.53 m. (a) What is the linear speed of the ball when it reaches the top of the ramp? ...
Ch 8.1 Earthquakes - LWC Earth Science
Ch 8.1 Earthquakes - LWC Earth Science

... Be able to understand why and where earthquakes occur. Be able to compare and contrast the epicenter and focus of an earthquake. ...
Newton`s Second Law of Motion
Newton`s Second Law of Motion

... The force of friction acts on any objects, which are in contact with each other ...
Lecture 2 Free Vibration of Single Degree of
Lecture 2 Free Vibration of Single Degree of

... For undamped single degree of freedom system, the application of Eq. (2.1) to mass m yields the equation of motion: ...
Gravity and Motion
Gravity and Motion

... Why Astronauts FloatOrbiting  An object is orbiting when it is traveling around another object in space.  When a spacecraft orbits Earth, it is moving forward at a constant speed. But the spacecraft is also in free fall toward earth.  By combining the movement forward with the ...
Vibrations, springs, and Hooke`s Law
Vibrations, springs, and Hooke`s Law

... An object is said to be in simple harmonic motion if the following occurs: •It moves in a straight line. •A variable force acts on it. •The magnitude of force is proportional to the displacement of the mass. •The force is always opposite in direction to the displacement direction. •The motion is rep ...
MOTION THE LAWS OF NEWTON
MOTION THE LAWS OF NEWTON

... compelled to change that state by forces impressed thereon. 2. The alteration of motion is ever proportional to the motive force impressed; and is made in the direction of the right line in which that force is impressed. 3. To every action there is always opposed an equal and opposite reaction: or t ...
Newton`s Second Law
Newton`s Second Law

NOTES Circular Motion
NOTES Circular Motion

... The sum of the forces equal to zero is not enough. The sum of the torques must also be zero. Examples of objects in static equilibrium: bridges, buildings, playground structures, or sawhorses. The torque is always taken about an axis of rotation. The axis can be placed at any location, but once plac ...
Getting Into Orbit
Getting Into Orbit

forces
forces

Physics I - Rose
Physics I - Rose

... Figure (a) shows velocity as downward, so the object is moving down. The length of the vector increases with each step showing that the speed is increasing (like a dropped ball). Thus, the acceleration is directed down. Since F  ma the force is in the same direction as the acceleration and must be ...
08
08

... force ( vector!) the person must exert on the mass after time t. The person’s co-ordinates at t = 0 is Rˆ1 ( in the ground frame) and the motion is counterclock-wise as seen from above. 38. A small body is placed on an incline which is pointed along the southern - northern direction. Find the angle ...
Magnitude 4.1 Bristol Channel, UK Thursday, 20 February, 2014 at
Magnitude 4.1 Bristol Channel, UK Thursday, 20 February, 2014 at

... Where was the earthquake felt? Most shaking was felt within a 125 km radius of the epicentre. Shaking was reported in Devon, Somerset, western Gloucestershire, Glamorganshire and Monmouthshire. Most people described weak to moderate shaking. The maximum recorded intensity was V (rather strong). I. I ...
Seismic Strengthening
Seismic Strengthening

111
111

... Part 1: 22 Multiple Choice Questions (1 mark each) Use: The acceleration of gravity g = 10 m/s2 and The universal gravitational constant G = 6.67x10-11 N.m2/kg2. The density of pure water = 1 g/cm3 = 1000 kg/m3 1) Which one of the following terms is used to indicate the natural tendency of an object ...
1.5 Newton`s Law of Motion
1.5 Newton`s Law of Motion

... The mass m of an object is a measure of its inertia. Inertia is the resistance of an object to change its state of rest or uniform motion. An object with the greater mass is more difficult to start or stop moving. ...
Chapter 6 Forces in Motion
Chapter 6 Forces in Motion

... • Projectile motion: the curved path an object follows when thrown or propelled near the surface of the Earth. • Projectile motion has 2 components horizontal and vertical and one has no impact on the other (independent). When combined, they formed a curved path. ...

Seismometer

Seismometers are instruments that measure motion of the ground, including those of seismic waves generated by earthquakes, volcanic eruptions, and other seismic sources. Records of seismic waves allow seismologists to map the interior of the Earth, and locate and measure the size of these different sources.The word derives from the Greek σεισμός, seismós, a shaking or quake, from the verb σείω, seíō, to shake; and μέτρον, métron, measure and was coined by David Milne-Home in 1841, to describe an instrument designed by Scottish physicist James David Forbes.Seismograph is another Greek term from seismós and γράφω, gráphō, to draw. It is often used to mean seismometer, though it is more applicable to the older instruments in which the measuring and recording of ground motion were combined than to modern systems, in which these functions are separated.Both types provide a continuous record of ground motion; this distinguishes them from seismoscopes, which merely indicate that motion has occurred, perhaps with some simple measure of how large it was.The concerning technical discipline is called seismometry, a branch of seismology.