Let P(x1, y1), Q(x2, y2), and M(x3, y3).
If M is the midpoint of PQ, then,
(x3, y3) = [(x1 + x2)/2, (y1 + y2)/2]
We need to verify that,
√[[(x1 + x2)/2 - x1]^2 + [(y1 + y2)/2 - y1]^2] = √[[x2 - (x1 + x2)/2]^2 + [y2 - (y1 + y2)/2]^2]]
Let's work separately in both sides. Left side:
√[[(x1 + x2)/2 - x1]^2 + [(y1 + y2)/2 - y1]^2]
= √[[(x1/2 + x2/2)]^2 - (2)(x1)[(x1/2 + x2/2)) + x1^2] + [(y1/2 + y2/2)]^2 - (2)(y1)[(y1/2 + y2/2)] + y1^2]]
= √[[(x1)^2]/4 + [(x1)(x2)]/2 + [(x2)^2]/4 - (x1)^2 - (x1)(x2) + (x1)^2 +[(y1)^2]/4 + [(y1)(y2)]/2 + [(y2)^2]/4 - (y1)^2 - (y1)(y2) + (y1)^2]]
= √[[(x1)^2]/4 - [(x1)(x2)]/2 + [(x2)^2]/4 + [(y1)^2]/4 - [(y1)(y2)]/2 + [(y2)^2]/4]]
Right side:
√[[x2 - (x1 + x2)/2]^2 + [y2 - (y1 + y2)/2]^2]]
= √[[(x2)^2 - (2)(x2)[(x1/2 + x2/2)] + [(x1/2 + x2/2)]^2 + [(y2)^2 - (2)(y2)[(y1/2 + y2/2)] + [(y1/2 + y2/2)]^2]]
= √[[(x2)^2 - (x1)(x2) - (x2)^2 + [(x1)^2]/4 + [(x1)(x2)]/2 + [(x2)^2]/4 + (y2)^2 - (y1)[(y2) - (y2)^2 + [(y1)^2]/4) + [(y1)(y2)]/2 + [(y2)^2]/4]]
= √[[(x1)^2]/4 - [(x1)(x2)]/2 + [(x2)^2]/4 + [(y1)^2]/4 - [(y1)(y2)]/2 + [(y2)^2]/4]]
Since the left and right sides are equals, the identity is true. Thus, the length of PM equals the length of MQ. As the result, M is the midpoint of PQ
The step to verify an isosceles triangle is: 1) Find the intersection points of the lines. 2) Find the distance for each intersection points. 3) If 2 of the distance are the same then it is an isosceles triangle.
100th of 300 hundred is 300th of 100th to the power of 300 times the dividend of 100 and 3, which equals 33 and one third but that's only if the quadratic formula is factorized into vertex and intercept form and then Chuck Norris must verify the answer.
Formula Auditing is one way. You can check the cell precedents with this. You can also do it by putting the cursor on the cell with the formula and pressing the Ctrl and the [ key. Whichever way you do it, the cells that the formula uses will be indicated. Formula auditing will show them with arrows and using the keyboard will select the cells.
Use absolute references. e.g. $B$12 instead of just B12.
The noun forms of the verb to verify are verifier, verification, and the gerund, verifying.
dont you know its in your textbook
The step to verify an isosceles triangle is: 1) Find the intersection points of the lines. 2) Find the distance for each intersection points. 3) If 2 of the distance are the same then it is an isosceles triangle.
A= 4 times the base of square mass
100th of 300 hundred is 300th of 100th to the power of 300 times the dividend of 100 and 3, which equals 33 and one third but that's only if the quadratic formula is factorized into vertex and intercept form and then Chuck Norris must verify the answer.
Double-click on the cell that contains a formula and look for what other cells are outlined. Those are the cells that are referenced by the formula.
True
True
Range finder. Double clicking on the formula activates the range finder and you can see what cells are in the formula. This can help you see if the correct cells are in the formula.
A={1,2,3,4} b={5,6,7,8,9} aub={1,2,3,4,5,6,7,8,9}
2003.2 You can use google maps distance to verify for yourself.
Alright, sweetheart, to verify the section formula by the graphical method, you'll need to draw a straight line and divide it at a certain ratio. Measure the lengths accurately, do some math, and if the ratios of the segments match the section formula, congratulations, you've verified it. Just make sure to dot your i's and cross your t's, darling.
Perpendicular distance is used while calculating movement in order to verify the calculation. The perpendicular calculation must match the original calculation.