Design and analysis of the proposed LPF

To analyze the LPF, we can calculate its transmission matrix (T). Then, by using it the conditions of loss reduction and transmission zeros can be determined. The transmission matrix of the lowpass section in Fig. 1 is obtained as follows:

(1)$$\eqalign{ & T = \left[{\matrix{ A \hfill & B \hfill \cr C \hfill & D \hfill \cr } } \right] = \left[{\matrix{ 1 \hfill & 0 \hfill \cr {Y_a} \hfill & 1 \hfill \cr } } \right]\times \left[{\matrix{ {\cos \theta } \hfill & {\,jz\sin \theta } \hfill \cr {\displaystyle{{\,j\sin \theta } \over z}} \hfill & {\cos \theta } \hfill \cr } } \right] \cr & \times \left[{\matrix{ 1 \hfill & 0 \hfill \cr {Y_b} \hfill & 1 \hfill \cr } } \right]\times \left[{\matrix{ {\cos \theta } \hfill & {\,jz\sin \theta } \hfill \cr {\displaystyle{{\,j\sin \theta } \over z}} \hfill & {\cos \theta } \hfill \cr } } \right]\times \left[{\matrix{ 1 \hfill & 0 \hfill \cr {Y_a} \hfill & 1 \hfill \cr } } \right]\to \cr {\rm where}\colon \hfill \cr A = & \cos ^2\theta + jzY_b\cos \theta \sin \theta -\sin ^2\theta \cr & + Y_a( 2jz\cos \theta \sin \theta -z^2Y_b\sin ^2\theta \cos \theta ) \hfill \cr B = & 2jz\cos \theta \sin \theta -z^2Y_b\sin ^2\theta \cos \theta \hfill \cr C = & ( Y_b + Y_a) \cos ^2\theta + \cos \theta \sin \theta \cr & \left({\displaystyle{2 \over z}j + jzY_aY_b\cos \theta -Y_a\sin \theta } \right) + Y_aD \hfill \cr D = & Y_ajz\sin \theta \cos \theta -\sin ^2\theta\; ( 1 + z^2Y_aY_b\cos ^2\theta ) \cr & + \cos ^2\theta\; ( jz( Y_b + Y_a) \sin \theta + 1) \hfill \cr {\rm and} \hfill \cr \theta = & \displaystyle{{\omega _c\sqrt {\varepsilon _{re}} } \over {300}}l} $$

where θ, l, ω_c, and ɛ_re are the electrical length, physical length (presented in Fig. 1), angular cut-off frequency of the LPF, and effective dielectric constant, respectively. The perfect impedance matching leads to decrease the return loss significantly. In equation (1), the matrices containing the terms of sinθ and cosθ are related to the transmission lines with the electrical length θ in Fig. 1 (lowpass part). The other matrices are related to the shunt stubs of the LPF. A high impedance matching is one of the factors which can help to decrease the return loss. To achieve this advantage, the reflection coefficient should be near zero. The reflection coefficient of the lowpass cell (Γ) is calculated as follows:

(2)$$\Gamma = \displaystyle{{A + B-C-D} \over {A + B + C + D}}$$

For perfect matching: Γ = 0. Therefore, A + B = C + D and as a result:

(3a)$$\eqalign{ & \,jz\left({Y_b + Y_a + 2-Y_a^2 -\displaystyle{2 \over {z^2}}} \right) = z[ Y_b + 2Y_a] \cot \theta \cr & \quad -Y_a\tan \theta + jz( Y_b + Y_a + 2Y_aY_b + Y_a^2 ) \cos \theta \cr & \quad + ( Y_aY_bz^2 + Y_bz^2 + Y_a) \sin \theta \cr & \quad -z^2Y_aY_b( 1 + Y_a) \sin \theta \cos \theta } $$

Due to the symmetrical structure of the LPF network, the reflection coefficient in the output port of the LPF is exactly the same as its input port. For predetermined values of cut-off frequency, ɛ_re and l, the above equation will be in terms of admittances. This means that from equation (3), for the predetermined values of cut-off frequency, dielectric constant, and the electrical length θ, we can adjust the values of shunt stubs. If the shunt cells are low-impedance, then we can write the following equation and replace it in equation (3a) as follows:

(3b)$$\eqalign{& \left\{\matrix{Y_b + Y_a + 2-\displaystyle{2 \over {z^2}}\langle \langle Y_a^2 \cr Y_b + Y_a\langle \langle 2Y_aY_b + Y_a^2 \hfill \cr Y_aY_bz^2\rangle \rangle Y_bz^2 + Y_a \hfill} \right.\to \cr zY_a^2 = & -j[ z[ Y_b + 2Y_a] \cot \theta -Y_a\tan \theta + jz( 2Y_aY_b + Y_a^2 ) \cos \theta \cr & \quad + ( Y_aY_bz^2) \sin \theta -z^2Y_aY_b( 1 + Y_a) \sin \theta \cos \theta ] } $$

For predetermined values of l = 6.5 mm, ɛ_re = 1.72 and 1.67 GHz cut-off frequency, we calculated θ = 17°. Then, we can simplify equation (3b) as follows:

(3c)$$\eqalign{zY_a^2 = & -j[ z3.2[ Y_b + 2Y_a] -0.3Y_a + 0.95jz( 2Y_aY_b + Y_a^2 ) \cr & \quad + 0.29( Y_aY_bz^2) -0.27z^2Y_aY_b( 1 + Y_a) ] } $$

From the above equation, we can obtain the ratio of shunt rectangular admittances which help us to easier optimization. The characteristic impedance z will be found based on the length and width of the transmission line as well as the dielectric layer thickness [Reference Hong and Lancaster16]. Equation (3) can be generalized for lowpass prototype filters with ladder equivalent circuit.

As presented in Fig. 1, our proposed LPF consists of three shunt stubs loaded on a simple transmission line. We have assumed that the two side stubs are similar and different from the middle stub. The transmission line with the physical length 2l at the low frequency will be short-circuited. Therefore, a short circuit path will be created between the input and output ports. Hence, it resonates at the low frequencies. The shunt stubs can be the cells filled with copper, which can be used to control the sharpness, harmonics S ₁₁, and insertion loss. Another choice of shunt stubs can be the step impedance cells. The LC model of step impedance cell includes capacitors and inductors. We can upgrade this basic structure to an LPF. The optimization method can be very helpful in improving the filter performance.

The layout of our LPF is presented in Fig. 2(a). We have placed all the stubs at the top of the transmission line so that there is enough space at the bottom to accommodate the bandpass resonator. This makes the size more compact. A large negative value of S ₁₁ in the passband is a transition pole. As shown in Fig. 2, a T-shape step impedance cell is embedded in the middle which can control the harmonics and create a transition pole, simultaneously. To increase the degree of freedom in controlling the frequency response, four rectangular cells are used. Instead of a rectangular resonator, any low-impedance resonators such as radial or triangular types can be utilized. In general, the space created by copper for moving the current is important. However, using the rectangular resonators helps to reduce the overall size. Therefore, we used the rectangular resonators instead of the other types of resonators. The overall dimensions of this resonator are obtained by the optimization method. Moreover, two tapped line feed structures are utilized to decrease the losses at the passband. The overall size of the designed LPF is 0.24 λ_g × 0.099 λ_g (33.9 mm × 14.1 mm), where λ_g is the guided wavelength calculated at the cut-off frequency of the lowpass channel. Hence, the normalized circuit size of this LPF is NCS = 0.023 ($\lambda _g^2$/mm²). The important physical dimensions in optimizing the frequency response are l_a, l_b, l_c, l_d, w_a, and w_b. The frequency response of the proposed LPF is shown in Fig. 2(b). The cut-off frequency and −20 dB stopband frequency of our LPF are f_c = 1.67 GHz and f_s = 1.88 GHz, respectively. It has an insertion loss (IL) of 0.047 dB and an S ₁₁ of −22.7 dB. The sharpness factor is ξ = 80.95 (dB/GHz), whereξ = 17/(f _s − f _c). The harmonics are attenuated up to 4.88 GHz with a maximum harmonic level of −20 dB. Therefore, it has a relative stopband bandwidth of RSB = Stop band Band width/fc = 1.93 with a suppression factor of SF = Maximum Harmonic Level/10 = 2. Our proposed LPF has a two-dimensional structure. Hence, it has an architecture factor of AF = 1. To compare with the other LPFs, having a high Figure Of Merit (FOM) is a good option where FOM = (ξ × SF × RSB)/(NCS × AF). The FOM of this LPF is 13585.52 which is good in comparison with the previous works. Another factor to compare LPFs is OFOM = FOM × RL/IL, where IL is the insertion loss. OFOM of our LPF is 6561517.94 which is a very good value. Another advantage of this LPF is its flat channel with a low group delay of 1.27 ns, where Fig. 2(c) depicts the group delay of our LPF. This LPF is simulated by ADS software (EM simulator) on an RT/Duroid 5880 substrate with ɛ_r = 2.22, h = 0.7874 mm, and tan (δ) = 0.0009. In this work, all simulation results are obtained on the above substrate using ADS software.

Fig. 2. Proposed LPF: (a) layout (unit: mm), (b) simulated S ₂₁ and S ₁₁, (c) group delay.

The dimensions of the designed LPF are optimized. The effects of changing physical dimensions on the frequency response are shown in Figs 3(a)–3(f). Changing the physical length l_a directly affects the harmonics. This is presented in Fig. 3(a), where decreasing l_a increases the harmonic level. On the other hand, by choosing an average value of this length we can create two transition poles at the passband. Another physical length that effects on harmonic level is l_b, which is depicted in Fig. 3(b). As shown in Fig. 3(b), having longer l_b leads to suppress the harmonics and better return loss (RL). Figures 3(c) and 3(d) show that by tuning l_c and l_d we can achieve lower RL. The simulation results show that wherever the RL is better, the IL is reduced. Figure 3(e) shows that the shunt stub with the physical width w_a has an important effect on the harmonic level, so that reducing w_a products some undesired harmonics. As shown in Fig. 3(f), by adjusting w_b, a transmission pole can be generated.

Fig. 3. Frequency response of the proposed LPF as functions of: (a) l_a, (b) l_b, (c) l_c, (d) l_d, (e) w_a, (f) w_b.

Design and analysis of the proposed BPF

The basic structure of our BPF is indicated in Fig. 4. The coupling effect is presented with three coupled capacitors of C ₁ which is an approximated model of coupled lines. Each transmission line is divided into two equal lines with the physical length l ₁, electrical length θ ₁, and characteristic impedance Z ₁. Also, we assume that the electrical length and characteristic impedance of spiral cell are θ ₂ and Z ₂ respectively.

Fig. 4. Basic structure of the proposed BPF.

The input admittance of this filter can be calculated as follows:

(4)$$Y_{in} = \displaystyle{1 \over {\displaystyle{1 \over {\displaystyle{1 \over {\displaystyle{1 \over {\displaystyle{1 \over {2jZ_1 \! \tan \! ( \! \theta _1 \!) \! + \! \displaystyle{1 \over {\,j\omega C_1}}}} \!+ \! j\omega C_1}} \! + \! 2jZ_1 \! \tan ( \theta _1) }} \! + \! j\omega C_1}} \!+ \! jZ_2 \! \tan ( \! \theta _2 \! ) }}$$

In equation (4), Z ₁ and Z ₂ are the characteristic impedances of the transmission line with the physical length l ₁ and the spiral cell, respectively. To obtain resonance frequencies, Y_in must be zero. Therefore, the angular resonance frequencies ω ₁ and ω ₂ can be calculated as shown in equation (5).

(5)$$\eqalign{& 3-8\omega C_1Z_1\tan ( \theta _1) + 4\omega ^2C_1^2 Z_1^2 \tan ^2( \theta _1) = 0 \cr & \Rightarrow \left\{{\matrix{ {\omega_2 = \displaystyle{{8C_1Z_1\tan ( \theta_1) -\sqrt {48C_1^2 Z_1^2 {\tan }^2( \theta_1) } } \over {8C_1^2 Z_1^2 {\tan }^2( \theta_1) }} = \displaystyle{{0.1} \over {C_1Z_1\tan ( \theta_1) }}} \hfill \cr {\omega_1 = \displaystyle{{8C_1Z_1\tan ( \theta_1) + \sqrt {48C_1^2 Z_1^2 {\tan }^2( \theta_1) } } \over {8C_1^2 Z_1^2 {\tan }^2( \theta_1) }} = \displaystyle{{1.8} \over {C_1Z_1\tan ( \theta_1) }}} \hfill \cr } } \right.}$$

Since we need a single-mode resonator, one of the angular resonance frequencies is a harmonic which should be attenuated or completely removed. From equation (5), if tan(θ ₁) is a large number, then the values of ω ₁ and ω ₂ will be close to each other. However, this method leads to a significant increasing of l ₁. Another way to get rid of this harmonic is to set it at a very high frequency. The characteristic impedance of Z ₁ can be obtained as follows [Reference Hong and Lancaster16]:

(6)$$\eqalign{Z_1 = & \displaystyle{{60} \over {\sqrt {\varepsilon _{re}} }}\ln \left({8\displaystyle{h \over {w_1}} + 0.25\displaystyle{{w_{_1 }} \over h}} \right)\,{\rm and}\,\displaystyle{w \over h} \le 1 \cr & {\rm where}\colon \cr \varepsilon _{re} = & \displaystyle{{\varepsilon _r + 1} \over 2} + \displaystyle{{\varepsilon _r-1} \over 2}\left[{\displaystyle{1 \over {\sqrt {1 + 12\displaystyle{h \over {w_1}}} }} + 0.04{\left({1-\displaystyle{{w_1} \over h}} \right)}^2} \right]} $$

Where ɛ_r, ɛ_re, h, and w ₁ are the dielectric constant, effective dielectric constant, thickness of dielectric, and the width of transmission line with physical length l ₁, respectively. If w ₁ = 0.3 mm, h = 0.7874 mm, and ɛ_r = 2.22, then from equation (6) ɛ_re = 1.72 and Z ₁ = 144.2 Ω. At a predetermined target resonance frequency of f_{r 1} = 2.6 GHz, the value of θ ₁ is (4.1l ₁)° which is calculated from equation (1). By replacing these values in equation (5), the following equation can be obtained:

(7)$$\eqalign{\omega _1 & = 2\pi f_{r1} = \displaystyle{{0.1} \over {144.2C_1\tan ( 4.1l_1) }}\Rightarrow C_1\tan ( 4.1l_1) \cr & \approx 4.24 \times 10^{{-}14}}$$

If l ₁ = 10.3 mm, then C ₁ will be 0.046 pF which is an acceptable value when the space between coupling lines is a little increased. Because C ₁ is a coupling capacitor that is usually a small value in pF, by increasing the space between coupled lines, the value of C ₁ is decreased. For l ₁ = 10.3 mm, the second angular resonance frequency can be obtained as follows:

(8)$$\eqalign{\omega _2 & = 2\pi f_{r2} = \displaystyle{{1.8} \over {144.2 \times 4.6 \times {10}^{{-}14} \times \tan ( 42.23) }} \cr & \Rightarrow f_{r2}\approx 47.5\,{\rm GHz}\Rightarrow f_{r2}\rangle \rangle f_{r1}}$$

Therefore, by placing the second resonance frequency at a far distance from the first one, we get rid of this harmonic. In the proposed BPF structure, l ₁ = 10.3 mm with 0.3 mm width so that the overall size of coupled lines is 20.6 mm. The proposed bandpass structure is carefully designed and directly connected to the LPF filter without any extra matching circuits. This leads to have a high-performance microstrip diplexer with good passband characteristics. To find the ABCD matrix and reflection coefficient of the BPF (T_B and Γ_B) we assumed that the impedances of the coupled lines and spiral cells are Z_C and Z_{S ,} respectively. Similar to the analysis of the LPF, T_B, Γ_B, and the condition for perfect matching (Γ_B = 0) can be obtained as follows:

(9)$$\eqalign{T_B = & \left[{\matrix{ 1 \hfill & {Z_C} \hfill \cr 0 \hfill & 1 \hfill \cr } } \right]\times \left[{\matrix{ 1 \hfill & 0 \hfill \cr {\displaystyle{1 \over {Z_S}}} \hfill & 1 \hfill \cr } } \right] = \left[{\matrix{ {1 + \displaystyle{{Z_C} \over {Z_S}}} \hfill & {Z_C} \hfill \cr {\displaystyle{1 \over {Z_S}}} \hfill & 1 \hfill \cr } } \right]\to \cr \Gamma _B = & \displaystyle{{\displaystyle{{Z_C} \over {Z_S}} + Z_C-\displaystyle{1 \over {Z_S}}} \over {2 + \displaystyle{{Z_C} \over {Z_S}} + Z_C + \displaystyle{1 \over {Z_S}}}} \cr \Gamma _B = & 0\to Z_C = \displaystyle{1 \over {1 + Z_S}}} $$

From equation (9), if Z_C = 1/(1 + Z_S) then we have a perfect matching in the output port of the BPF.