Want this question answered?
Partial measures output/(single input)Multi-factor measures output/(multiple inputs)Total measure output/ (total inputs)Productivity =(Outputs/inputs)
Efficiency = ( useful energy output / total energy input ) x 100
The equilibrium price is the unit cost, which is the same as the total cost divided by the number of units produced (output).
Net words per minute is your total words with the error rate calculated into the result. Gross words per minute is the total words typed, without subtracting any errors.
7 gallons x 9 = 63 gallons 1 quart x 9 = 9 quarts = 2 and 1/4 gallons Hence total is 65 and 1/4 gallons
The sympathetic nervous system increases blood pressure by increasing cardiac output, which is the amount of blood ejected by the heart per minute. It also increases total peripheral resistance, which is the resistance to blood flow in the blood vessels. These actions help to increase blood pressure in response to stress or other physiological demands.
Cardiac output is the total volume of blood that is pumped by the heart per minute. When you exercise, there is a greater demand for oxygen, which is carried in your blood, thus your cardiac output increases.
True
yes
Cardiac output is the blood volume pushed out by the left ventricle per minute. Stroke volume is the volume of blood pushed out of the left ventricle per contraction of the heart (each heart beat). So stroke volume into heart rate / minute gives you cardiac output.
Parallel resistance refers to 2 or more resistors where the input sides are connected together and the output sides are connected together. The formula to calculate it is the inverse of the total resistance of the circuit is equal to the sum of the inverses of the individual resistances. 1/R (total) = 1/R (1) + 1/R (2) + 1/R (3) + …
15% according to Guyton Textbook of Medical Physiology. 50-55ml per 100grams brain tissue per minute, or 750ml blood per minute.
its total resistance in ckt
A growth in the total output produced.
Negative
Total power output (Total RMS output): 1000 watts
The energy delivered by a battery would depend on-- the battery's voltage-- the resistance of the load connected across its output terminals-- the length of the time the load is connectedThe power delivered by the battery is [ (voltage)2 divided by (load resistance) ].The total energy delivered by the battery is [ (power) multiplied by (time the load is connected) ].