Muscle contraction. In a study of the speed of muscle contraction in frogs under various loads, British biophysicist A. W. Hill determined that the weight w in grams placed on the muscle and the speed of contraction v in centimeters per second are approximately related by an equation of the form w + a v + b = c where a , b , and c are constants. Suppose that for a certain muscle, a = 15 , b = 1 , and c = 90. Express v as a function of w . Find the speed of contraction if a weight of 16 g is placed on the muscle.
Muscle contraction. In a study of the speed of muscle contraction in frogs under various loads, British biophysicist A. W. Hill determined that the weight w in grams placed on the muscle and the speed of contraction v in centimeters per second are approximately related by an equation of the form w + a v + b = c where a , b , and c are constants. Suppose that for a certain muscle, a = 15 , b = 1 , and c = 90. Express v as a function of w . Find the speed of contraction if a weight of 16 g is placed on the muscle.
Solution Summary: The author calculates the speed of contraction vin centimeter per second if a weight is placed on the muscle.
Muscle contraction. In a study of the speed of muscle contraction in frogs under various loads, British biophysicist A. W. Hill determined that the weight
w
in grams
placed on the muscle and the speed of contraction
v
in centimeters per
second
are approximately related by an equation of the form
w
+
a
v
+
b
=
c
where
a
,
b
,
and
c
are constants. Suppose that for a certain muscle,
a
=
15
,
b
=
1
,
and
c
=
90.
Express
v
as a function of
w
. Find the speed of contraction if a weight of
16
g
is placed on the muscle.
Refer to page 100 for problems on graph theory and linear algebra.
Instructions:
•
Analyze the adjacency matrix of a given graph to find its eigenvalues and eigenvectors.
• Interpret the eigenvalues in the context of graph properties like connectivity or clustering.
Discuss applications of spectral graph theory in network analysis.
Link: [https://drive.google.com/file/d/1wKSrun-GlxirS3IZ9qoHazb9tC440 AZF/view?usp=sharing]
Refer to page 110 for problems on optimization.
Instructions:
Given a loss function, analyze its critical points to identify minima and maxima.
• Discuss the role of gradient descent in finding the optimal solution.
.
Compare convex and non-convex functions and their implications for optimization.
Link: [https://drive.google.com/file/d/1wKSrun-GlxirS31Z9qo Hazb9tC440 AZF/view?usp=sharing]
Refer to page 140 for problems on infinite sets.
Instructions:
• Compare the cardinalities of given sets and classify them as finite, countable, or uncountable.
•
Prove or disprove the equivalence of two sets using bijections.
• Discuss the implications of Cantor's theorem on real-world computation.
Link: [https://drive.google.com/file/d/1wKSrun-GlxirS31Z9qoHazb9tC440 AZF/view?usp=sharing]
Chapter 2 Solutions
Finite Mathematics for Business, Economics, Life Sciences and Social Sciences Plus NEW MyLab Math with Pearson eText -- Access Card Package (13th Edition)
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