Acceleration day one

After glancing at the approach taken last January, I decided to attempt a parallel approach this fall and tread along the edge of calculus.


I began with a graph of a medium speed velocity of 3.5 meters per second from the 11:00 class last Thursday. I then made a second graph of time versus velocity. I noted that the 2.88 second time recorded at 10 meters was only an approximate time. I then showed that the area under the velocity line in the second graph was the distance: 2.88 seconds horizontally × 3.5 meters per second vertically is 10.08 meters. In other words, the time × velocity is the distance - which is exactly what d = vt expresses. Distance is velocity × time. 


The third graph was another time versus velocity graph, but here I supposed that each second my velocity would be one meter per second faster. So I would start at 0 meters per second at time zero, be moving at one meter per second at one second, increase my speed again to two meters per second by the two second mark, and be moving at three meters per second after three seconds. 

Using the formula for a triangle where the area equals ½base × height to obtain the distance covered yields distance of 0.5 meters, 2 meters, 4.5 meters, and 8 meters at 1, 2, 3, and 4 seconds respectively. Plotting these values back onto a time versus distance graph yields a curve. Arguably, but not proven to be, a parabola. For now, a curve that appears that it could be parabolic.  But is this what will happen?

At 12:26 the class returned to the sidewalk. The red lines are at Fibonacci numbers: 1, 2, 3, 5, and 8 meters. Use of the Fibonacci sequence has worked well in recording temperatures for cooling curves. The ever increasing distances work against "timing rhythms" developing.


A number of students recorded the RipStik acceleration data, the above times were from Kamaloni. The data is clearly non-linear. The curvature is well matched by a quadratic equation. This doesn't prove that the data is parabolic, but the data provides support for this model. The acceleration was 0.45 meters per second per second, or 0.45 meters/second². The ½ in the equation for distance versus time can be conceived of having originated in the formula for the area of a triangle. This is not strictly true, but sorting this out properly is usually done with calculus.

An example of this demonstration can be seen in the following video.


Did my speed increase at a constant rate? Was there a linear rise in velocity?

Graph

The orange data points show that the rate of increase in speed of the RipStik was unsteady. The data, however, is roughly linear and does not appear to curve in a particular direction. Accelerating a RipStik in a steady fashion is challenging.

Comments

Post a Comment

Popular posts from this blog

Plotting polar coordinates in Desmos and a vector addition demonstrator

Image
In an earlier post I noted that Desmos did not directly plot polar coordinates. Not only was I incorrect, but Desmos responded to my blog to correct me! Although I had at some point seen that one could define a function f(x)=3x+5 and then have Desmos calculate f(6), I had not absorbed how this might be used to plot polar coordinates. The above works beautifully . Realizing that I could effectively program Desmos, I applied this thinking to demonstrating how to add two vectors when given the magnitudes m and the direction angles theta. The graph calculates the i and j components for the two vectors and then adds the vectors, graphically displaying the result while also providing information on the magnitude and direction of the vector sum. m1 and theta1 are the magnitude and direction angle for one of the two vectors, m2 and theta2 are the magnitude and direction for the other vector. All four are dynamically interactive and can be changed. The diagram purports to illustra
Read more

Setting up a boxplot chart in Google Sheets with multiple boxplots on a single chart

Image
The  Google Statistics  add-on for Google Sheets can display multiple boxplots in a single chart. The key is the layout of the data. One column should be the variable by which the data is to be grouped, the other column should be the data to be box plotted. Set up the Statistics add-on with the data to be plotted as the variable, and the grouping column as the "by" variable. In this image I had deselected all but the boxplot option, the result was the appearance of the Moment, Standard errors, and Confidence intervals options. The default is apparently a 95% confidence interval for the mean. The result is multiple boxplots on a single chart with a common scale. The new tab that is created also quotes 95% confidence intervals for the mean. Note that as of 2018 the Google Statistics add-on cannot be found by search in the add-ons. In addition, as of May 2018 the add-on no longer verifies, possibly due to the add-on not having been updated since August 2017. One may ha
Read more

Traditional food dishes of Micronesia

Image
Clara, Jennette, and Joanie presented ground hard taro cooked in an umw, effectively a hot rock oven. Pohnpeian: rotama. Pingelapese: sero. Mwoakillese: rodma. Mortlockese: Amahd. Kosrae: rodoma. After cooking in an umw the rotama is pounded with the petiole of a palm frond. Rotama is made from hard or swamp taro, known as mwahng on Pohnpei, mweian on Pingalap, pula in Mortlockese, and pahsruhk on Kosrae. In traditional times on the outer islands the women had primary responsibility for tending the taro while the men handled fishing and climbing tasks. Joesen and Noeleen presented fermented breadfruit from the outer islands of Yap such as Woleai and Eauripik. The raw ingredients were actually brought in from Yap, Noeleen prepared the maare.  The leaf wrap is ti leaf - Cordyline fruticosa. Pauleen, Barnson, Trisha, Verginia, Con-ray, and Maylanda from Kitti, Pohnpei brought in mahi umw, koahpnoair koakihr, and uht sukusuk. Above is breadfruit umw, mahi umw, one o
Read more