Transmission Lines d a a b w h Two wire open line Strip line Coaxial Cable

Two Wire Open Line Consider a plane wave propagating along the z-direction in vacuum, and polarized with its electric vector along the x-axis: its magnetic field vector must be directed along the y-axis. Now introduce two infinitely conducting metal planes which block of all of space except the region between x= +a and x= -a, see Figure above. The boundary conditions at x=  a that must be satisfied by the electric and magnetic fields are: (1) the tangential components of E must be zero; (2) the normal component of H must be zero. E x = E 0 exp (i[kz -  t]), H y = (E 0 /Z 0 ) exp (i[kz-  t]).

A strip-line. The electric field has only an x-component, if edge effects are neglected, and in the first approximation this component is independent of position across the width of the strip, i.e. E x is independent of y. Similarly, the magnetic field has only a y- component and this is independent of x and y. E x = E 0, V = E 0 d, H y = E 0 =Z 0, I=wJ s =w(E 0 /Z 0 ).

Co-axial Line The electric field has a radial component, E r, and the magnetic field has only the component H  independent of the angle . H y =  0 c G(z + ct) = -E x /Z 0

Transmission

Two wire open line The field distribution due to a pair of wires

Two wire open line Line Behavior When the switch is closed how long does the lamp take before it lights? If we make it easy and let the length of the wires between battery and lamp be m, then the time between the switch closing and lamp lighting will be approximately ______s.

Two wire open line Does this mean that electrons are traveling at the speed of light?Does this mean that electrons are traveling at the speed of light? Does it mean that the mechanism relies on electromagnetic energy being transported from start to finish of the structure?Does it mean that the mechanism relies on electromagnetic energy being transported from start to finish of the structure? If so where is the energy stored during transit?If so where is the energy stored during transit? If it is electromagnetic energy that is stored then it has to be stored in inductance for magnetic energy and capacitance for electric energy.If it is electromagnetic energy that is stored then it has to be stored in inductance for magnetic energy and capacitance for electric energy. This means that the transmission line has to have an inductance (per unit length) and a capacitance (per unit length).This means that the transmission line has to have an inductance (per unit length) and a capacitance (per unit length).

Two wire open line Low Loss line at High Frequency Inductance and capacitance are uniformly and continuously distributed as L (Henrys/m) and C (Farads/m) respectively. When the switch is closed and a voltage V is applied to the line through a source impedance Zs, simple reasoning shows that the C's take a finite time to charge up through the L's; thus, the voltage propagates at a finite rate towards the load i.e. volts do not reach the load instantaneously.

Transmission in Capacitive Element Let L and C be distributed inductance and capacitance per unit length. In time  t, electric flux  q = (C ·  x)v ( Q = CV) is produced in time  x/u sec, and produced in time  x/u sec, and i(amps) =  q/  t = C  x v/  t (capacitive charging or "displacement" current) i = C  x v /(  x/ u ) = Cvu (I)

Transmission in Magnetic Element In time  t, magnetic flux linkages  =(L  x)i (from  = LI) ; are produced in time  x/u sec v(volts) =  /  t = L  xi/  t=Liu (ind Volts)…(II) Multiplying I and II:- vi =vi CLu 2 Or u = 1/  LC ms -1 velocity of propagation Dividing I by II:- i/v =vC/iL or v 2 /i 2 =L/C v/I =  L/C……Characteristic Impedance Z 0

Energy Transmission v 2 v 2 i2i2 = L C ; i 2 L = v 2 C ½ Li 2 = ½ Cv 2 Note:- the equality of Electric and Magnetic field energy in unit length of transmission line.

Movement of Energy Rate of energy input to line due to advance of wavefront, is vi watts. resistive load, connected directly to voltage source. Rate of energy input, due to thermal dissipation in R, is vi watts (also i 2 R).

Movement of Energy Rate of energy input = vi watts. Idea of a 'matched line': looks like an infinitely long line. Note: if R g = Z 0, maximum power if transferred from the generator to the line.

Movement of Energy As can be seen from the intuitive picture of a transmission line, wave propagation characteristics are dependent on the inductance and capacitance of the line. Thus we need to find expressions for the L and C of typical lines.

Inductance in Two wire line Inductance Assume r << S Due to conductor A, for 1 amp Linkages per metre, axially, L

Inductance in Two wire line Due to conductor B, an identical expression is Obtained:-

Mutual Inductance Between 2 Twin Lines External field due to 1 amp in line A, at radius

Mutual Inductance Between 2 Twin Lines Flux linkages per metre axially through circuit (between conductor 1 & 2) is :- B =  =

Capacitance two wire line Capacitance of a Twin Line (r << S) Assign a line charge of 1 C/m to both conductors. D at x from conductor A is;

Capacitance two wire line and Similarly for VB(=VA) 

R, L, C of Two wire line per unit length per unit length  2A22A2 ohm/m L = 00  log e d a H/m C = 00 log e (d/a) F/m R dc = log e

Z 0 Twin-wire line For air, therefore Z 0 = 120 log e (b/a), (approx ) L = 00  d a Characteristic Impedence log e 00 log e (d/a) C =