In Problem 3.1, an engineering student walk a 200m line to determine his pace factor. Another route was taken by the said student while his passometer record the number of his pace as shown in the table. Using his pace factor, determine the length of theroute. Since we know the pace factor of the observer, we can use it to calculate the distanceof the new line. Calculate the average number of paces that covered the new line.713 + 711.5 + 715 + 713.54x = 713.25pacesTo determine the distance of the new line, we can multiply the paces which covers itand the computed pace factor of the observant.d= Pace Factor x Npacesd = (0.7339m/pace)(713.25paces)d = 523.4542mThe pace factor of the engineering student is 0.7339m/pace and the length of thenew measured line is 523.4542m.Problem 3.6In Problem 3.1, an engineering student walk a 200m line to determine his pace factor.Another route was taken by the said student while his passometer record the numberof his pace as shown in the table. Using his pace factor, determine the length of theroute.Recorded Number ofPacesTrial196529623970 Sample Problem 3.1The first activity in a surveying class is the determination of the pace factor. Anengineering student wak a 100m line for the said activity for four times and herecorded the number of his paces. Another new line was paced for four trials with thefollowing results on the table.Number of Pace to Cover100m LineTrialthe New Line11357132138711.531367154136713.5Determine the pace factor and the distance of the new line.Solution:To determine the pace factor, we need to calculate the average number of paces tocover 100m.135 + 138 + 136 + 1364*= 136. 25 pacesCVE 202F: FUNDAMENTALS OF SURVEYING FIELDWORK 45We know that the pace factor is the ratio of a known distance over the number of pacesto cover it. With these, we can say that the pace factorPace Factor meanyredNgaces100m136.25pacesPace Factor =Pace Factor 0.7339m/paceSince we know the pace factor of the observer, we can use it to calculate the distanceof the new line. Calculate the average number of paces that covered the new line.713 + 711.5 + 715 + 713.54X = 713.25paces

Given data- Engineering student walk a 200m line

In Problem 3.1, an engineering student walk a 200m line to determine his pace factor. Another route was taken by the said student while his passometer record the number of his pace as shown in the table. Using his pace factor, determine the length of the route.

In Problem 3.1, an engineering student walk a 200m line to determine his pace factor. Another route was taken by the said student while his passometer record the number of his pace as shown in the table. Using his pace factor, determine the length of the route.

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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Question

Since we know the pace factor of the observer, we can use it to calculate the distance
of the new line. Calculate the average number of paces that covered the new line.
713 + 711.5 + 715 + 713.5
4
x = 713.25paces
To determine the distance of the new line, we can multiply the paces which covers it
and the computed pace factor of the observant.
d= Pace Factor x Npaces
d = (0.7339m/pace)(713.25paces)
d = 523.4542m
The pace factor of the engineering student is 0.7339m/pace and the length of the
new measured line is 523.4542m.
Problem 3.6
In Problem 3.1, an engineering student walk a 200m line to determine his pace factor.
Another route was taken by the said student while his passometer record the number
of his pace as shown in the table. Using his pace factor, determine the length of the
route.
Recorded Number of
Paces
Trial
1
965
2
962
3
970

Sample Problem 3.1
The first activity in a surveying class is the determination of the pace factor. An
engineering student wak a 100m line for the said activity for four times and he
recorded the number of his paces. Another new line was paced for four trials with the
following results on the table.
Number of Pace to Cover
100m Line
Trial
the New Line
1
135
713
2
138
711.5
3
136
715
4
136
713.5
Determine the pace factor and the distance of the new line.
Solution:
To determine the pace factor, we need to calculate the average number of paces to
cover 100m.
135 + 138 + 136 + 136
4
*= 136. 25 paces
CVE 202F: FUNDAMENTALS OF SURVEYING FIELDWORK 45
We know that the pace factor is the ratio of a known distance over the number of paces
to cover it. With these, we can say that the pace factor
Pace Factor meanyred
Ngaces
100m
136.25paces
Pace Factor =
Pace Factor 0.7339m/pace
Since we know the pace factor of the observer, we can use it to calculate the distance
of the new line. Calculate the average number of paces that covered the new line.
713 + 711.5 + 715 + 713.5
4
X = 713.25paces

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