Selection of our books indexed in the Book Citation Index in Web of Science™ Core Collection (bkci)
Figure 27. Circuit with a capacitor Figure 28
Yüklə 1,41 Mb. Pdf görüntüsü
|
- Bu səhifədəki naviqasiya:
- 4.3. Inductor
|
Figure 27. Circuit with a capacitor
Figure 28. Circuit with inductor For the equation idt =Cdu , integrating both sides yields the following formula: ∫ u 0 u Cdu = ∫ t 0 t idt , or u(t)= 1 C ∫ t 0 t idt + u 0 ( t 0 ) If t 0 =0 , above equation can be simplified to u(t)= 1 C ∫ t 0 t idt + u 0 (0) and for t 0 = −∞ , above equation reduces to u(t)= 1 C ∫ −∞ t idt The initial voltage in above equation, u 0 ( t 0 ) , is usually defined with the same polarity as u , which means u 0 ( t 0 ) is a positive quantity. If the polarity of u 0 ( t 0 ) is in the opposite direction, then u 0 ( t 0 ) is negative. Advances in Bioengineering 210 4.3. Inductor An inductor in figure 28 is a passive element that is to store energy in magnetic field and is made by winding a coil of wire around a core that is a insulator or a ferromagnetic material. A magnetic field is established when current flows through the coil. The symbol is utilized to represent the inductor in a circuit. The unit of measurement for inductance is the Henry or Henries (H). The relationship between voltage and current for inductor is given by u = L di dt The convention for writing the voltage drop across an inductor is similar to that of a resistor. Physically, current cannot change instantaneously through a inductor since an infinite voltage required. Mathematically, a step change in current through an inductor is possible by applying a voltage. For convenience, when a circuit has just DC currents (or voltages), the inductors can be replaced by short circuits, since voltage drops across the inductors are zero. After producing current on the both sides of equation, the following expression can be acquired after integration: ∫ 0 t uidt = ∫ 0 i Lidi = 1 2 L i 2 Above expression demonstrates that magnetic energy increases with the increase of current through inductor component. In this course, electrical energy could be converted into magnetic energy, namely inductor acquires energy from the source. Formula 1 2 L i 2 is the magnetic energy of inductive element. When current decreases, magnetic energy decreases and then is converted into electric energy, namely inductor releases energy to the source. Hence, inductor is not a dissipative element, but a energy storage element, too. For the equation udt = Ldi , integrating both sides yields the following formula: ∫ t 0 t u(t)dt = ∫ i ( t 0 ) i(t) Ldi , or, i(t)= 1 L ∫ t 0 t u(t)dt + i ( t 0 ) If t 0 =0 , above equation can be simplified to i(t)= 1 L ∫ t 0 t u(t)dt + i(0) and for t 0 = −∞ , above equation reduces to i(t)= 1 L ∫ −∞ t u(t)dt Biomedical Sensor, Device and Measurement Systems http://dx.doi.org/10.5772/59941 211 The initial current in above equation, i ( t 0 ) , is usually defined with the same polarity as i , which means i ( t 0 ) is a positive quantity. If the polarity of the initial current i ( t 0 ) is in the opposite direction, then i ( t 0 ) is negative. Yüklə 1,41 Mb. Dostları ilə paylaş:
|