Economics: P= Price and Q = Quantity Demanded.
According to the ideal gas law, pressure times volume is constant. We'll call that constant c. PV=C, P=c/V, so pressure is inversely related to volume, so it would look like the graph y=1/x multiplied by a constant.
Suppose the sides of the rectangle ABCD are not parallel to the axis. Then if A = (p,q) and B = (r, s) then by Pythagoras, |AB|2 = (p - r)2 + (q - s)2 from which AB can be calculated. Calculate BC in a similar fashion and then area = AB*BC If AB is parallel to an axis (say the x axis), then q = s so that q - s = 0 and |AB|2 simplifies to (p - r)2 + 02 so that |AB| = |p - r|
-36y - 3 All you do is do twelve times three which is thirty six so you add the y to it. You cant do anything with the three because it doesn't have a letter.
It is the gradient of the straight line joining the origin to any point on the graph. Thus, if A = (p,q) is any point on the graph, the average unit rate between the origin and A is q/p (provided p is non-zero).
H-P-O Axis means Hypothalamus-Pitutary-Ovarian Axis, which is the basic function for mensuration cycle in women
Just look at the graph of a function.If a polynomial P(x) has a squared factor such as (x - c)^2, then x = c is a double root of P(x) = 0. In this case, the graph of y = P(x) is tangent to the x-axis at x = c.If a polynomial P(x) has a cubic factor such as (x - c)^3, then x = c is a triple root ofP(x) = 0. In this case, the graph of y = P(x) flattens out around (c, 0), and crosses the x-axis at this point.
The first graph is clear. But the second graph shows demand's relation to price and supply. Now let's say supply decreases; then p will rise (q = constant, p = >). If demand decreases, then p will decrease as well. When both curves decrease, you will face different situations. How much have they decreased is the main question. Has demand decreased more or less than supply? Let's assume this. So then price will decrease as well (compared to Poriginal).
you can't....it's merely impossible! Assuming it is a graph of velocity vs time, it's not impossible, it's simple. Average velocity is total distance divided by total time. The total time is the difference between finish and start times, and the distance is the area under the graph between the graph and the time axis.
According to the ideal gas law, pressure times volume is constant. We'll call that constant c. PV=C, P=c/V, so pressure is inversely related to volume, so it would look like the graph y=1/x multiplied by a constant.
Because power dissipated in rl circuit is given by p= 1/2(Li²)+ i²R which will give a curve and not a linear graph. Secondly the graph is a cosine curve ,with a phase difference between current and voltage. Hence the waveform is not symmetrical to x-axis .
Suppose the sides of the rectangle ABCD are not parallel to the axis. Then if A = (p,q) and B = (r, s) then by Pythagoras, |AB|2 = (p - r)2 + (q - s)2 from which AB can be calculated. Calculate BC in a similar fashion and then area = AB*BC If AB is parallel to an axis (say the x axis), then q = s so that q - s = 0 and |AB|2 simplifies to (p - r)2 + 02 so that |AB| = |p - r|
T = Title U = Units L = Labels I = Integers P = Plot Optional- S = Summary
-36y - 3 All you do is do twelve times three which is thirty six so you add the y to it. You cant do anything with the three because it doesn't have a letter.
It's x = 0. Consider a point of the plane, P=(x, y), in cartesian coordinates. If P is a point belonging to x-axis, then P=(x, y=0); if P is a point belonging to y-axis, then P=(x=0, y).
=kinds of graph are the pictograph, bar graph, pie or circle graph and the line graph.==that's all.==i wish a can help u.!=haha!:P
H. P. Yap has written: 'Some topics in graph theory' -- subject(s): Graph theory
of Stand, imp. & p. p. of Stand.