Vo=(R2/R1)(V2-V1)
Here is qn excellent article that explains step by step: http://MasteringElectronicsDesign.com/how-to-derive-the-instrumentation-amplifier-transfer-function/
The equation for the average over time T is integral 0 to T of I.dt
AC RMS Value x 1.414
the Taylor series of sinx
You'll find ordinary differential equations (ODEs) being used in chemical engineering for many things, such as determining reaction rates, activation energies, mass transfer operations, heat transfer operations, and momentum transfer operations.
here we r going to see about the derivation of the reset gain... the instrumentation amplifier which has got two stages that is gain stage and differential stage
Here is qn excellent article that explains step by step: http://MasteringElectronicsDesign.com/how-to-derive-the-instrumentation-amplifier-transfer-function/
To derive integrability conditions for a Pfaffian differential equation with ( n ) independent variables, one typically employs the theory of differential forms and the Cartan-Kähler theorem. The first step involves expressing the Pfaffian system in terms of differential forms and then analyzing the associated exterior derivatives. By applying the conditions for integrability, such as the involutivity condition (closure of the differential forms), one can derive necessary and sufficient conditions for the existence of solutions. Ultimately, this leads to the formulation of conditions that the differential forms must satisfy for the system to be integrable.
derive clausious mossotti equation
equation of ac machine
help plzz
Philosophy of Mathematics is a place in math where on would derive an equation. It is the branch of philosophy that studies the: assumptions, foundations, and implications of mathematics.
General gas Equation is PV=nRT According to Boyls law V
The equation for the average over time T is integral 0 to T of I.dt
R1/r2=r3/r4
The most accurate way to model a pendulum (without air resistance) is as a differential equation in terms of the angle it makes with the vertical, θ, the length of the pendulum, l, and the acceleration due to gravity, g. d²θ/dt² = -g*sin(θ)/l There is no easy way to integrate this to get θ as a function of time, but if you assume θ is small, you can use the small angle approximation sin(θ)~θ which makes the equation d²θ/dt² = -g*θ/l Which can then be integrated to get the solution θ(t)=θmax*sin(t*√(g/l)) Using this equation, you can easily derive that the period of the pendulum (time required to go through one full cycle) would be T=2π*√(l/g) If air resistance is also accounted for in the original differential equation, the exact equation will be much harder to derive, but in general will involve an exponential decay of a sin function.
The proof of the Schrdinger equation involves using mathematical principles and techniques to derive the equation that describes the behavior of quantum systems. It is a fundamental equation in quantum mechanics that describes how the wave function of a system evolves over time. The proof typically involves applying the principles of quantum mechanics, such as the Hamiltonian operator and the wave function, to derive the time-dependent Schrdinger equation.