Examples of Force-Length Relationship in the following topics:
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- The force a muscle generates is dependent on its length and shortening velocity.
- The force a muscle generates is dependent on the length of the muscle and its shortening velocity.
- If this attachment was
removed, for example if the bicep was detached from the scapula or radius, the muscle would shorten in length.
- In mammals, there is a strong overlap between the optimum and actual resting length of sarcomeres.
- The force-velocity relationship in muscle relates the speed
at which a muscle changes length with the force of this contraction and the
resultant power output (force x velocity = power).
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- The shortening velocity affects the amount of force generated by a muscle.
- The force-velocity relationship in muscle relates the speed at which a muscle changes length to the force of this contraction and the resultant power output (force x velocity = power).
- The force generated by a muscle depends on the number of actin and myosin cross-bridges formed; a larger number of cross-bridges results in a larger amount of force.
- Though they have high velocity, they begin resting before reaching peak force.
- As velocity increases force and power produced is reduced.
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- We want to describe the relationship between the head length and total length variables in the possum data set using a line.
- In this example, we will use the total length as the predictor variable, x, to predict a possum's head length, y.
- We could fit the linear relationship by eye, as in Figure 7.7.
- A scatterplot showing head length against total length for 104 brushtail possums.
- A point representing a possum with head length 94.1mm and total length 89cm is highlighted.
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- The ratio of force to area $\frac{F}{A}$ is called stress and the ratio of change in length to length $\frac{\Delta L}{L}$ is called the strain.
- A change in shape due to the application of a force is a deformation.
- Even very small forces are known to cause some deformation.
- The ratio of force to area $\frac{F}{A}$ is called stress and the ratio of change in length to length $\frac{\Delta L}{L}$ is called the strain.
- Tension: The rod is stretched a length $\Delta L$ when a force is applied parallel to its length.
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- Even very small forces are known to cause some deformation.
- Strain is the change in length divided by the original length of the object.
- Experiments have shown that the change in length (ΔL) depends on only a few variables.
- Additionally, the change in length is proportional to the original length L0 and inversely proportional to the cross-sectional area of the wire or rod.
- Tension: The rod is stretched a length ΔL when a force is applied parallel to its length.
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- Viewing them as simple machines, the input force is much greater than the output force, as seen in .
- Very large forces are also created in the joints.
- Because muscles can contract but not expand beyond their resting length, joints and muscles often exert forces that act in opposite directions, and thus subtract.
- Forces in muscles and joints are largest when their load is far from the joint.
- Training coaches and physical therapists use the knowledge of the relationships between forces and torques in the treatment of muscles and joints.
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- Quadratic relationships between variables are commonly found in physical sciences, engineering, and elsewhere.
- Quadratic relationships between variables are commonly found in physical sciences, engineering, and elsewhere.
- Perhaps the most universally used example of quadratic relationships in problem solving concerns right triangles.
- This says that the square of the length of the hypotenuse ($c$) is equal to the sum of the squares of the two legs ($a$ and $b$) of the triangle.
- The equation relating electrostatic force ($F$) between two particles, the particles' respective charges ($q_1$ and $q_2$), and the distance between them ($r$) is very similar to the aforementioned formula for gravitational force:
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- Such plots permit the relationship between the variables to be examined with ease.
- Figure 7.4 shows a scatterplot for the head length and total length of 104 brushtail possums from Australia.
- The head and total length variables are associated.
- Possums with an above average total length also tend to have above average head lengths.
- Straight lines should only be used when the data appear to have a linear relationship, such as the case shown in the left panel of Figure 7.6.
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- Length is a physical measurement of distance that is fundamentally measured in the SI unit of a meter.
- Length can be defined as a measurement of the physical quantity of distance.
- The distance between objects, the rate at which objects are traveling, and how much force an object exerts are all dependent on length as a variable.
- Many different units of length are used around the world.
- The basic unit of length as identified by the International System of Units (SI) is the meter.
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- Similarly, the C-H bond length can vary by as much as 4% between different molecules.
- At internuclear distances in the order of an atomic diameter, attractive forces dominate.
- At very small distances between the two atoms, the force is repulsive and the energy of the two atom system is very high.
- The attractive and repulsive forces are balanced at the minimum point in the plot of a Morse curve.
- Identify the relationship between bond energy and strength of chemical bonds