An Ideal pendulum is ones that would be the first choice if you could choose all the materials (ideal materials). A practical pendulum is one that is readily available and reliable (made from things you have right now and are available to use).
What is the difference between ideal and actual cycle?
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Ideal transformer is useful in understanding the practical transformer..i does't have losses...
The difference between theoretical and actual voltage gain can arise from several factors, including non-ideal components, parasitic elements, and circuit loading effects. Real-world components often have tolerances and limitations that deviate from ideal characteristics, such as resistance, capacitance, and inductance. Additionally, the interaction between components can introduce unintended feedback or loss, impacting the overall gain. Environmental factors, such as temperature or frequency, can also influence performance, leading to discrepancies between theoretical predictions and practical results.
The real practical cycle refers to the actual performance of thermodynamic cycles, such as the Carnot, Otto, or Rankine cycles, in real-world applications. Unlike ideal theoretical cycles, which assume perfect conditions and efficiency, practical cycles account for irreversibilities, heat losses, friction, and other non-ideal factors that occur in real engines and systems. While these practical cycles are based on the principles of ideal cycles, they often operate at lower efficiencies and have more complex behaviors due to these real-world influences.
Zener diode is heavily doped pn junction diode.
What is the difference between ideal and actual cycle?
no we cannot realize an ideal simple pendulum because for this the string should be weightless and inextendible.
Ideal sources refer to the most accurate and reliable sources of information available, while practical sources are those that are readily accessible and convenient to use, even if they may not be as reliable or comprehensive. It is important to balance ideal and practical sources when conducting research to ensure accuracy and efficiency.
No. Anything called "ideal" in science (ideal pendulum, ideal lever, ideal gas, etc.) is an approximation of the real thing, used to simplify calculations. A real pendulum may get fairly close to an ideal pendulum, and similar in other "ideal" things, but it will never be exactly the same.
The ideal age difference should be between 4 and 7.
Compound pendulum is a physical pendulum whereas a simple pendulum is ideal pendulum. The difference is that in simple pendulum centre of mass and centre of oscillation are at the same distance.
Compound pendulum is a physical pendulum whereas a simple pendulum is ideal pendulum. The difference is that in simple pendulum centre of mass and centre of oscillation are at the same distance.
A simple pendulum consists of : . Bob of very small size .suspended by a weightless, inextensible flexible string There are ideal parameters. so,No it is not possible to realize an ideal simple pendulum in practice , because these conditions could not be fullfilled 100%.
The ideal model of a simple pendulum assumes the pendulum mass is concentrated at a single point, the string or rod is massless and frictionless, and the pendulum moves in a vacuum with no air resistance. Additionally, it assumes small amplitude oscillations, and the only force acting on the pendulum is gravity.
A simple pendulum consists of : . Bob of very small size .suspended by a weightless, inextensible flexible string There are ideal parameters. so,No it is not possible to realize an ideal simple pendulum in practice , because these conditions could not be fullfilled 100%.
An ideal pendulum is one in which no air resistance or friction is present. Hence when set into motion it never loses energy to it's surrondings. So when released, and left to swing, the energy potential it had get's convertedinto kinetic energy and therefore the pendulum swings. When it reaches it's amplitude(Highest swing) the energy is converted back to potential, and as it falls back to kinetic. As it is "ideal" it never loses energy to heat/ friction. Therefore, the conversion of kinetic energy to potential etc etc will always be constant and it will never stop. Although in reality it is impossible to have an "ideal" pendulum, near ideal ones can be obtained by suspending the pendulum in a vacuum.