Serratus Anterior 1. ABDUCTION of Shoulder Girdle Joint 2. UPWARD ROTATION of Shoulder Girdle Joint Pectoralis Minor 1. ABDUCTION of Shoulder Girdle Joint Pectoralis Major 1. FLEXION of Shoulder Joint 2. HORIZONTAL FLEXION of Shoulder Joint 3. MEDIAL (INTERNAL) ROTATION of Shoulder Joint Rhomboid Minor 1. ADDUCTION of Shoulder Girdle Joint 2. DOWNWARD ROTATION of Shoulder Girdle Joint Rhomboid Major 1. ADDUCTION of Shoulder Girdle Joint 2. DOWNWARD ROTATION of Shoulder Girdle
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Lab: Newton’s Law of Motion Section #: 404 Group #: 3 Experiment #: 3 Date :October 16‚ 2012 Newton’s Law of Motion Your signature indicates that you have completely read the entire report and agree with everything here in. Failure to sign will result in a zero for your personal grade unless a formal exception is filed with your TA. Please Print and Sign Full Name Principal investigator: Skeptic ________________________________________________________ Researcher:
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TAP 601-1: Brownian motion Brownian motion (named after the botanist Robert Brown) is the presumably random drifting of particles suspended in a fluid (a liquid or a gas) or the mathematical model used to describe such random movements‚ which is often called a particle theory. The experiment of Brownian motion in a smoke cell is a classic experiment that gives strong circumstantial evidence for the particulate nature of air. Materials: ✓ Smoke cell‚ incorporating a light source
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haL76442_ch02_029-060.indd Page 29 29/03/11 9:11 AM user-f494 /204/MHDQ284/haL76442_disk1of1/0073376442/haL76442_pagefiles C Kinematic Concepts for Analyzing Human Motion H A P T 2 After completing this chapter‚ you will be able to: Provide examples of linear‚ angular‚ and general forms of motion. Identify and describe the reference positions‚ planes‚ and axes associated with the human body. Define and appropriately use directional terms and joint movement terminology
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industrial Technology Boni Avenue‚ City of Mandaluyong “Motion Study and Micro-motion Study Equipment” Artiga‚ Odiboy R. Espiritu‚ Robert C. Course/Year: BSIE 3rd year Subject: Methods Engineering Day/Time: Monday/Thursday 10:30am-12:00pm Instructor: Engr. Nestor Japis Motion study involves the analysis of the basic hand‚ arm‚ and body movements of workers as they perform work. Work design involves the methods and motions used to perform a task. This design includes the workplace
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Running Head: MOTION AND GRAPHICAL ANALYSIS Motion and Graphical Analysis Lab 3 Qiling Yang PHY 101‚ Online Professor Gregory Stafford July 21‚ 2013 Motion and Graphical Analysis Laboratory exercise 3 covers two experiments which are intended to analyze application of laws of motion. Objectives By the end of this two-experiment laboratory‚ students ideally will know how to analyze displacement‚ velocity
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Chapter 28 RANGE OF MOTION EXERCISES What You Will Learn • The purposes of range of motion exercises • Types of range of motion exercises • The In-Home Aide’s responsibilities when giving range of motion exercises • How to give range of motion exercises according to proper procedure Purposes of Range of Motion Exercises (ROM) The musculoskeletal system must be exercised to remain healthy. ROM exercises prevent joints from becoming stiff and contractures (deformities)
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| Projectile Motion Lab | | | | Projectile Motion Lab | | | March 14‚ 2012 Authored by: Abby Buchanan and Zack Sloope March 14‚ 2012 Authored by: Abby Buchanan and Zack Sloope Projectile Motion Lab Predictions: Angle: The angle will affect the height. Initial Speed: This will affect the distance and force. Mass of Projectile: It affects how much force is needed. Size and Shape of Projectile: It will affect the distance. Terms: Range: distance an object goes
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Projectile Motion PHYS111 Formal Report 2 University of Canterbury Campbell Moulder Abstract The force of gravity is said to be a constant of 9.81 ms-2 (3). This can be proved by measuring the projectile motion of a bouncy ball and plotting a ∆Vertical Velocity vs. Time graph‚ the gradient of which should equal the constant force (acceleration due to) of gravity. Our gradient value of 10.26±0.49 ms-2 is consistent with the actual value of 9.81 ms-2. Introduction A projectile is an
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2. LINEAR MOTION In this experiment you will study the motion of an object in one dimension from a number of points of view. You will demonstrate how the variables of motion are related by differentiation and integration and investigate the relationship between potential and kinetic energy. Theory Why Study Motion? Motion is everywhere in the universe. Only at a temperature of absolute zero is the motion in any body truly absent. If motion exists then so also does energy. To the delight of
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