GUIDED WAVES IN A RECTANGULAR WAVE GUIDE

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GUIDED WAVES IN A RECTANGULAR WAVE GUIDE Consider waves propagating along Oz but with restrictions in the and/or directions. The wave is now no longer necessaril transverse. The wave equation can be written as In the present case this becomes and similarl for. There are three kinds of solution possible: TEM H z = E z = 0, i.e. the familiar transverse EM waves TE E z = 0 TM H = 0 z It can be shown (Griffiths p.407 (390)) that TEM waves do not occur in hollow waveguides. Boundar conditions We assume the guides to be perfect conductors so of E at a boundar implies that t = 0 inside the guides. Hence, the continuit E t = 0 in the wave guide at the boundar. E n is not necessaril zero in the wave guide at the boundar as there ma be surface charges on the conducting walls (the solution given below implies that there are such charges) It follows from Mawell's equation (ME1, see p.5) that because = 0, is also zero inside the conductor (the time dependence of is ep(-i t)). The continuit of H implies that H n = 0 at the boundar. There are currents induced in the guides but for perfect conductors these can be onl surface currents. Hence, there is no continuit for H t. This is to be contrasted with the boundar condition used for waves reflecting off conducting surfaces with finite conductivit. The standard geometr for a rectangular wave guide is given fig 1. A wave can be guided b two parallel planes for which case we let the planes at = 0, a etend to = ±. n 1

Figure 1 TE Modes: B definition, E z = 0 and we start from as the wave equation in Cartesian coordinates permits the use of the separation of variables. TM Modes: B definition, H z = 0 and we start from It is customar in wave guides to use the longitudinal field strength as the reference. For the parallel plate wave guide there is no dependence so just set Y = 1. TE modes Using the above form for the solution of the wave equation, the wave equation can be rewritten as the minus signs being chosen so that we get the oscillator solutions needed to fit the boundar conditions. Now appl the boundar conditions to determine the restrictions on H z. At = 0, a: E = 0 and H = 0 (E is zero everwhere) z 2

For the following Griffith's writes down all the Mawell equations specialised to propagation along 0z. I will write just those needed for the specific task and motivate the choice. Use the route that ou prefer. We need to relate E, H to the reference H z. Hence, we use the component of ME2 (which has 2 H fields and 1 E field) (1) The first term is ik H which is zero at the boundar. z Consequentl, at = 0, a and X = cos k with The absence of an arbitrar constant upon integration is justified below. At = 0, b: E = 0 and H = 0 and we now use the component of ME2 (2) As the second term is proportional H we get at = 0, b and Y = cos k with. The general solution is thus However, m = n = 0 is not allowed for the following reason. When m = n = 0, H z is constant across the waveguide for an plane. Consider the integral version of Farada's law for a path that lies in such a plane and encircles the wave guide but in the metal walls. As E = 0 in the conducting walls and the time dependence of is given b ep(-i t) this equation requires that. We need onl evaluate the integral over the guide as = 0 in the walls. For constant B z this gives Bab z = 0. So B z = 0 as is H z. However, as we have chosen E z = 0 this implies a TEM wave which cannot occur inside a hollow waveguide. Adding an arbitrar constant would give a solution like 3

which is not a solution to the wave equation... tr it. It also equivalent to adding a solution with either m = 0 or n = 0 which is a solution with a different Cut off frequenc 2 This restriction leads to a minimum value for k. In order to get propagation k z > 0. Consequentl, Suppose a > b then the minimum frequenc is c /a and for a limited range of (dependent on a and b) this solution (m = 1, n = 0, or TE ) is the onl one possible. 10 The other fields Awa from the boundaries, equation 1 gives where H z means that cos k has been replaced b sin k. We need another relation between E and either H or H z, which must come from the other Mawell equation (ME1). We have to decide which component of ME1 to use. If we choose the z component, the equation involves E and E, introducing another unknown field (E ). However, the component involves E and E z. As E z = 0, this gives the required relation. So Substituting in the above gives Similarl from equation 2 and the component of ME1 4

we get Velocit The phase velocit v p is given b However the group velocit is given b TM modes The boundar conditions are easier to appl as it is E z itself that is zero at the boundaries. Consequentl, the solution is readil found to be Note that the lowest TM mode is due to the fact that E z 0. Otherwise, along with H z = 0, the solution is a TEM mode which is forbidden. The details are not given here as the TM wave between parallel plates is an assignment problem. It can be shown that for ohmic losses in the conducting walls the TM modes are more attenuated than the TE modes. MAXWELL EQUATIONS 2003-11-07 5

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