Citations and Corresponding Text Blocks
This document lists specific source citations mapped to their corresponding transcribed text blocks for Chapters 24 and 23. The layout uses a small table cell for the citation identifier and a much larger table cell for the transcribed content, with mathematical symbols styled accordingly.
24_JBECT_All.pdf (Chapter 24: Application of Complex Numbers to Series AC Circuits)
| Citation | Corresponding Text Block |
|---|---|
| [1040-1042] | AC circuits may be analysed by using complex numbers for simplified phasor diagrams. |
| [1043-1044] | In pure resistance the circuit in polar equation is given by: |
| [1044] | Z = (VR∠0°) / (IR∠0°) = R |
| [1055-1059] | In pure inductance the current lags the applied voltage by 90°. |
| [1058-1064] | Z = (VL∠90°) / (I∠0°) = XL∠90° = jXL |
| [1075-1076] | The voltage lags the current by 90° in this circuit. |
| [1091] | Z = (VC∠-90°) / (IC∠0°) = XC∠-90° = -jXC |
| [1092-1093] | Where XC is 1 / ωC. |
| [1096-1098] | -jXC = -j / ωC = 1 / jωC |
| [1123-1125] | The current is said to be lagging even though the phase is +90° as the current is behind the voltage. |
| [1144-1146] | V = IZ, and VC = IXC |
| [1177-1178] | |Z| = √(R2 + (XL – XC)2), φ = tan-1((XL – XC) / R) Z = R + j(XL – XC) = |Z|∠φ |
| [1179-1184] | In an a.c. circuit containing several impedances connected in series, say Z1, Z2, Z3 … Zn, the total equivalent impedance is given by: |
| [1186] | ZT = Z1 + Z2 + Z3 + … + Zn |
| [1187-1191] | For a circuit containing parallel impedances Z1, Z2 and Z3, the potential difference is the same and equal to the supply voltage V. |
| [1204-1205] | ZT = (Z1Z2) / (Z1 + Z2) |
23_JBECT_All.pdf (Chapter 23: Revision of Complex Number)
| Citation | Corresponding Text Block |
|---|---|
| [1214-1221] | Complex numbers can be used to represent anything that is periodic. They are used in Laplace transforms and Fourier transforms, and are used to analyze varying voltages and currents. |
| [1243-1246] | The written form (for example, 2+j2) is said to be in cartesian or rectangular form. |
| [1251] | An anticlockwise change of direction is an increase in phase. |
| [1276] | Addition is straightforward enough. |
| [1278] | (a+jb)(c+jd) = (ac-bd) + j(ad+bc) |
| [1284-1286] | The product of a complex number and its conjugate (having the same number but with the complex part having a minus sign, i.e., a-jb) is a2 + b2. This property is used when dividing complex numbers. |
| [1296] | (1+2j)/(3-4j) × (3+4j)/(3+4j) = ((1×3) – (2×4)j) / (32+42) = (3-8j) / 25 |
| [1303-1312] | If two complex numbers are equal, then their real parts are equal and their imaginary parts are equal. |
| [1337-1339] | z = x+jy = r\cos heta + j r\sin heta This is usually abbreviated to z = r∠θ, which is called the polar form of a complex number. |
| [1345-1347] | It is determined by Pythagoras’s theorem: |z| = r = √(x2+y2). |
| [1349-1350] | θ is called the argument and is written arg z. It is deduced from θ = an^{-1}(y/x). |
| [1362] | r1∠θ1 × r2∠θ2 = r1r2∠(θ1+θ2) |
| [1365] | (r1∠θ1) / (r2∠θ2) = (r1/r2)∠(θ1-θ2) |
| [1370] | (r∠θ)n = rn∠nθ |
| [1374] | √(r∠θ) = r1/2∠(½θ) |