To calculate the enthalpy change or heat energy of a phase change, use the formula q=m(heat of (fusion, vaporization, etc...)). Make sure to use the formula q=mc(delta T) to calculate the heat energy for the temperature changes in between phase changes. Add up all of the q values and you have your enthalpy change.
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Hammer piston velocity is: Velocity of an pneumatic cylinder can be calculated as s = 28.8 q / A (1) where s = velocity (inches/sec) q = volume flow (cubic feet/min)A = piston area (square inches) Do you know how to calculate the impact PSI? - This is where I get lost.
No. Specific heat capacity (c) is used in to calculate energy when matter is not undergoing a phase change [Q = mc(delta)T]. Heat of fusion (HF) is used to calculate energy when matter is either melting or freezing [Q = m(HF)].
That depends on what information is provided. If you don't have any information, you may actually need to measure the speed of the water; or you may want to measure the flow (for example, in liters per second), and the pipe diameter, and then calculate the speed from that.
Important Formula: Sin(q) = Opposite / Hypotenuse Cos(q) = Adjacent / Hypotenuse Tan(q) = Opposite / AdjacentSelect what (angle / sides) you want to calculate, then enter the values in the respective rows and click calculate. If you want to calculate hypotenuse enter the values for other sides and angle.
Ifp < q and q < r, what is the relationship between the values p and r? ________________p
p = q
The truth values.
Choose some values for x. Then calculate the corresponding values of y using the formula. Put these values in a table.Choose some values for x. Then calculate the corresponding values of y using the formula. Put these values in a table.Choose some values for x. Then calculate the corresponding values of y using the formula. Put these values in a table.Choose some values for x. Then calculate the corresponding values of y using the formula. Put these values in a table.
The KLD is more or less a measure of how much information is lost when an approximation is used to replace an actual probability distribution. How you calculate it depends on whether you are considering discrete or continuous values for the distribution. If you have discrete values, KLD = Σ P(i) log [P(i)/Q(i)] (summing over the values of i) where P(i) is the "true" distribution and Q(i) a corresponding approximation. If you have a continuous function for the probability, i.e. the variable can assume any value over a certain range (usually with different probability density for different values since uniform probability is a pretty boring problem) KLD = ∫ p(x)log[p(x)/q(x)] dx (integrated from -∞ to +∞) where p(x) is the true function of the probability - the "density" of P, and q(x) is the approximated function of the probability - the "density" of Q. Note that these formulas only hold for a single variable. More complex formulas are required to calculate the KLD for multi-variable distributions.
p=q
p/q form of the number is 0.3 is: (A) (B)
If you mean point of (-1, 3) with a gradient of -2 and point (5, 2) with a gradient of -1 then as straight line equations they work out as y = -2x+1 and y = -x+4 respectively. As to the values of p and q not enough information has been given.
V= q/a
The values of p and q work out as -2 and 4 respectively thus complying with the given conditions.
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