CALCULATIONS The experimental value for the acceleration of gravity obtained is g=9.17m/s (experimental value). We can...

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CALCULATIONS The experimental value for the acceleration of gravity obtained is g=9.17m/s² (experimental value). We can show that this differs from the value g = 9.8m/s² by 100% (9.80-9.17)/9.80 = 6.4% the percentage of error. Use the experimental data in column L2 to calculate the experimental value of g and its percentage error deviation from 9.8m/s². g= m/s² % error % CALCULATIONS for the inclined plane experiment Use the last equation to calculate the experimental data, values of L, h, and the average of t to calculate the experimental value of g. Call the value obtained from this calculation gexp and compare it to the value of the acceleration of gravity at sea level g = 9.8 m/s². DATA: L1 L2 L3 1.91 1.95 1.9 1.88 1.95 1.95 1.93 2.02 1.93 2.15 2.05 2.02 2.06 1.91 L3(1)=1 L1 1.93 1.93 2.05 L2 L3 3 2.02 2.15 2.02 4 TIL 2.06 1.9 1.95 1.9 1.91 1.85 1.88 1.91 L3(10)=10 10 1-Var Stats L1 1-Var Stats x-1.948 Ex-19.48 Ex=37.979 Sx-.0595911999 ax=.9565331761 ↓n=10 1-Var Stats fn=10 minx=1.9 Q1-1.9 Med=1.93 Q3=1.95 maxX=2.06 The data stored in column L1 was used to calculate the average of 10 values of t for the inclined plane experiment shown as x bar = 1.948 obtained by the TI-84 calculator 1-Var Stats L1 feature. We can use the values: h=0.23m L = 2.0m t=1.948s (experimental data) CALCULATIONS for the inclined plane experiment Use the last equation to calculate the experimental data, values of L, h, and the average of t to calculate the experimental value of g. Call the value obtained from this calculation gexp and compare it to the value of the acceleration of gravity at sea level g = 9.8 m/s². DATA: L1 L2 L3 3 1.91 1.95 1.9 1.88 1.95 1.95 1.95 1.55 2.05 2.06 L3(1)=1 L1 1.93 1.93 2.05 1.9 L3 3 4 TIL 2.06 1.9 1.95 2.02 2.15 2.02 1.91 1.85 1.88 1.91 1.9 L3(10) 10 1-Var Stats L1 1-Var Stats 8-1.948 1-Var Stats fn=10 Ex=19.48 Ex²=37.979 ox=.0565331761 Sx=.055211229 Med=1.23 Q1=1.9 Q=1.95 +n=10 maxx-2.06 The data stored in column L1 was used to calculate the average of 10 values of t for the inclined plane experiment shown as x bar = 1.948 obtained by the TI-84 calculator 1-Var Stats L1 feature. We can use the values: h=0.23m L = 2.0m t=1.948s (experimental data) CALCULATIONS for the inclined plane experiment Use the last equation to calculate the experimental data, values of L, h and the average of t to calculate the experimental value of g. Call the value obtained from this calculation gexp and compare it to the value of the acceleration of gravity at sea level g = 9.8 m/s². DATA: L1 L2 1.91 1.95 19 1.88 1.95 1.93 2.0% CALCULATIONS The experimental value for the acceleration of gravity obtained is g-9.17m/s² (experimental value). We can show that this differs from the value g 9.8m/s² by 100 % (9.80-9.17)/9.80 6.4% the percentage of error. Use the experimental data in column L2 to calculate the experimental value of g and its percentage error deviation from 9.8m/s². LXCD1 L1 .93 05 L2 2.02 2.02 191 DE 2.06 1.9 LX10)=10 1-Var Stats Li 1-Var Stats 8-1.948. 1-Var Stats fn=10 Sx σχε .48. 979 5911299 91-1.9 inx-1.9 Med-1.93 1761 Q-1.95 In-10 maxx-2.06 The data stored in column L1 was used to calculate the average of 10 values of t for the inclined plane experiment shown as x bar 1.948 obtained by the TI-84 calculator 1-Var Stats L1 feature. We can use the values: h=0.23m t-1.948s (experimental data) L-2.0m 9= % error m/s² CALCULATIONS The experimental value for the acceleration of gravity obtained is g = 9.17m/s² (experimental value). We can show that this differs from the value g = 9.8m/s² by 100% (9.80 -9.17)/9.80 = 6.4% the percentage of error. Use the experimental data in column L2 to calculate the experimental value of g and its percentage error deviation from 9.8m/s². Column L2 g= 1.95 m/s² 1.88 1.95 2.02 2.15 % error % 2.02 1.91 1) CALCULATIONS The experimental value for the acceleration of gravity obtained is g=9.17m/s² (experimental value). We can show that this differs from the value g = 9.8m/s² by 100% (9.80-9.17)/9.80 = 6.4% the percentage of error. Use the experimental data in column L2 to calculate the experimental value of g and its percentage error deviation from 9.8m/s². g= m/s² % error % CALCULATIONS for the inclined plane experiment Use the last equation to calculate the experimental data, values of L, h, and the average of t to calculate the experimental value of g. Call the value obtained from this calculation gexp and compare it to the value of the acceleration of gravity at sea level g = 9.8 m/s². DATA: L1 L2 L3 1.91 1.95 1.9 1.88 1.95 1.95 1.93 2.02 1.93 2.15 2.05 2.02 2.06 1.91 L3(1)=1 L1 1.93 1.93 2.05 L2 L3 3 2.02 2.15 2.02 4 TIL 2.06 1.9 1.95 1.9 1.91 1.85 1.88 1.91 L3(10)=10 10 1-Var Stats L1 1-Var Stats x-1.948 Ex-19.48 Ex=37.979 Sx-.0595911999 ax=.9565331761 ↓n=10 1-Var Stats fn=10 minx=1.9 Q1-1.9 Med=1.93 Q3=1.95 maxX=2.06 The data stored in column L1 was used to calculate the average of 10 values of t for the inclined plane experiment shown as x bar = 1.948 obtained by the TI-84 calculator 1-Var Stats L1 feature. We can use the values: h=0.23m L = 2.0m t=1.948s (experimental data) CALCULATIONS for the inclined plane experiment Use the last equation to calculate the experimental data, values of L, h, and the average of t to calculate the experimental value of g. Call the value obtained from this calculation gexp and compare it to the value of the acceleration of gravity at sea level g = 9.8 m/s². DATA: L1 L2 L3 3 1.91 1.95 1.9 1.88 1.95 1.95 1.95 1.55 2.05 2.06 L3(1)=1 L1 1.93 1.93 2.05 1.9 L3 3 4 TIL 2.06 1.9 1.95 2.02 2.15 2.02 1.91 1.85 1.88 1.91 1.9 L3(10) 10 1-Var Stats L1 1-Var Stats 8-1.948 1-Var Stats fn=10 Ex=19.48 Ex²=37.979 ox=.0565331761 Sx=.055211229 Med=1.23 Q1=1.9 Q=1.95 +n=10 maxx-2.06 The data stored in column L1 was used to calculate the average of 10 values of t for the inclined plane experiment shown as x bar = 1.948 obtained by the TI-84 calculator 1-Var Stats L1 feature. We can use the values: h=0.23m L = 2.0m t=1.948s (experimental data) CALCULATIONS for the inclined plane experiment Use the last equation to calculate the experimental data, values of L, h and the average of t to calculate the experimental value of g. Call the value obtained from this calculation gexp and compare it to the value of the acceleration of gravity at sea level g = 9.8 m/s². DATA: L1 L2 1.91 1.95 19 1.88 1.95 1.93 2.0% CALCULATIONS The experimental value for the acceleration of gravity obtained is g-9.17m/s² (experimental value). We can show that this differs from the value g 9.8m/s² by 100 % (9.80-9.17)/9.80 6.4% the percentage of error. Use the experimental data in column L2 to calculate the experimental value of g and its percentage error deviation from 9.8m/s². LXCD1 L1 .93 05 L2 2.02 2.02 191 DE 2.06 1.9 LX10)=10 1-Var Stats Li 1-Var Stats 8-1.948. 1-Var Stats fn=10 Sx σχε .48. 979 5911299 91-1.9 inx-1.9 Med-1.93 1761 Q-1.95 In-10 maxx-2.06 The data stored in column L1 was used to calculate the average of 10 values of t for the inclined plane experiment shown as x bar 1.948 obtained by the TI-84 calculator 1-Var Stats L1 feature. We can use the values: h=0.23m t-1.948s (experimental data) L-2.0m 9= % error m/s² CALCULATIONS The experimental value for the acceleration of gravity obtained is g = 9.17m/s² (experimental value). We can show that this differs from the value g = 9.8m/s² by 100% (9.80 -9.17)/9.80 = 6.4% the percentage of error. Use the experimental data in column L2 to calculate the experimental value of g and its percentage error deviation from 9.8m/s². Column L2 g= 1.95 m/s² 1.88 1.95 2.02 2.15 % error % 2.02 1.91 1)

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Given Acceleration of gravity g 97 ms 2 experimental value By using the column of ... View the full answer