Loaded-line phase shifter

A loaded-line phase shifter is composed of a transmission line periodically loaded by shunt-susceptances. Varactor-diodes are commonly employed as the loading, as depicted in Fig 1. In the illustration, there is a T-unit cell (UC) that consists of two transmission lines of length $d/2$, and with a shunt-loaded varactor diode in between. The transmission line has an inductance per unit cell length L_t and a capacitance per unit cell length C_t. The varactor-diode has a voltage-controlled capacitance $C_V(V_R)$, where V_R is the reversed bias voltage. The transmission line has an unloaded impedance Z ₀, and the effective characteristic impedance Z_e of the unit cell can be expressed as

(1)\begin{align} Z_e &= \sqrt{ \frac{L_t}{C_t+C_V(V_R)/d} }.\nonumber \\ &= \sqrt{ \frac{L_t}{C_t}}\times\frac{1}{\sqrt{1+IF(V_R)}}\nonumber \\ &= Z_0\frac{1}{\sqrt{1+IF(V_R)}} \end{align}

Figure 1. Illustration of the periodic loaded-line phase shifter with N number of T-unit cells.

where

(2)\begin{equation} I_F = \frac{C_V(V_R)}{C_t d} \end{equation}

is known as the inclusion factor. Under the condition C_V $\gg$ $C_t d$, (1) can be simplified to

(3)\begin{equation} Z_e = \sqrt{ \frac{L}{C_V(V_R)}}, \end{equation}

where $L = L_td$ is the inductance per unit cell.

Equation (1) is valid as long as the frequency is far below the Bragg frequency f_B, which is defined as the frequency where the period d between two varactor-diodes is equal to half of the guided wavelength λ_g. In terms of the loaded-line phase shifter parameters, the Bragg frequency [Reference Rodwell, Kamegawa, Yu, Case, Carman and Giboney17] is

(4)\begin{equation} f_{B} = \frac{1}{\pi d\sqrt{L_tC_t(1+I_F(V_R))}}. \end{equation}

To achieve a large phase shift, both L and C_V shall be large, and to obtain a large L the unloaded transmission line is of high-impedance. The capacitance $C_V(V_R)$ changes with the bias condition, and only one bias point will achieve a perfect match with the system impedance. Therefore, the phase shifter will be mismatched when tuning the phase and there will be two extreme bias points of V _min and V _max. When designing a phase shifter, the differential phase shift $\Delta\phi$ is of interest, which is defined as the phase shift between the two extreme bias points and is expressed as follows

(5)\begin{equation} \Delta\phi = \beta(V_{\textrm{min}})-\beta(V_{\textrm{max}}). \end{equation}

In reality, an increased phase shift normally comes with increased attenuation due to mismatch and dissipation. For this reason, a phase-shift/loss FOM is introduced

(6)\begin{equation} F_{\Delta\phi} = \frac{\Delta\phi_{\textrm{degree}}}{L_{\textrm{dB}}}, \end{equation}

where L _dB is the total loss in the phase shifter.

Varactor-diode modeling

Under normal operation, the varactor-diodes in a loaded-line phase shifter are reversed biased and, therefore, the nonlinear capacitance of the varactor is of primary interest in the model. An equivalent circuit model of the reversed bias varactor is presented in Fig. 2(a) that is composed of a series inductance (L_s), a series resistance (R_s), a parallel capacitance (C_p), and the variable junction capacitance (C_j). The model parameters can be extracted with the real and imaginary parts of the measured impedance

(7)\begin{equation} Z(V_R) = R_s + j\left( \omega L_s - \frac{1}{\omega C_V(V_R)}\right), \end{equation}

Figure 2. (a) Equivalent circuit model of reversed bias varactor-diode. The extracted values are L_s = 1.51 nH and R_s = 1.49 Ω, where the polynomial coefficients of C_V = C_j + C_p are presented in Table 1. For comparison, the datasheet values are L_s = 0.7 nH, R_s = 1.2 Ω, C_p = 0.81 pF, and C_j is solved by (8) with $C_{j0}$ = 4.21 pF, ϕ = 11.87 V, and n = 6.43. (b) Illustration of two-port network employed to extract varactor parameters. Pad dimensions are l_p = 0.5 mm and w_p = 0.4 mm. Thru line dimensions are l_t = 8 mm and w_t = 1.183 mm.

Table 1. Values of the polynomial coefficients utilized to model the varactor’s C-V characteristics

where $C_V(V_R) = C_j(V_R) + C_p$. The variable junction capacitance can be modeled by

(8)\begin{equation} C_j(V_R) = \frac{C_{j0} \phi ^n}{(\phi + V_R)^n} , \end{equation}

where $C_{j0}$ is the zero bias junction capacitance of the diode, ϕ is the built-in potential, and n is the grading coefficient [Reference Maas18]. Equation (8) (referred to as the standard C_V model in this paper) has been demonstrated to predict the C-V characteristics of semiconductor varactors well. The model’s accuracy depends on the doping profile of the p-n junction. In the case of a uniformly doped and linearly graded junction, the model has good accuracy. However, when the doping profile is highly nonuniform, the standard C_V model can have difficulty modeling the C-V characteristics. In that case, it is more suitable to model the C-V characteristics as a polynomial series expressed as

(9)\begin{equation} C_j(V_R) = C_0 + C_1 V_R + C_2 V_R^2 + ... + C_n V_R^n, \end{equation}

where C_n is the polynomial coefficient of the nth-order.

Polynomial varactor model extraction

The experimental work reported in this paper is based on a hyperabrupt varactor of model Skyworks SMV1233-079LF, chosen due to its low loss and good tuning range. Figure 2(b) depicts a two-port network utilized to extract the varactor’s model parameters. The two-port network comprises a shunt varactor and two transmission lines connecting it to the input and output, forming a T-network. Hence, the varactor’s impedance in (7) corresponds to Z ₁₂ of the two-port network. To obtain Z ₁₂, the two-port network’s S-parameters were measured, and the effects of the transmission lines were de-embedded. Then, Z ₁₂ was calculated from the de-embedded S-parameters. Two pads were employed to connect the varactor with a small amount of solder paste, and the pads and solder paste add inductance and losses. In the phase shifter simulation presented later in the paper, the varactor is directly connected from the transmission line to the ground. The contribution of the pads and solder paste is embedded in the varactor model. The modeled bias range of the varactor should be larger than the bias range of the phase shifter to properly model the nonlinear behavior because it has to cover the radio frequency (RF)voltage swing. Therefore, the varactor was measured for a bias range of 0.3 V to −12 V.

The C-V characteristics were obtained from the imaginary part of (7) at a low frequency of 200 MHz, where the inductor’s contribution is negligible. A polynomial curve fitting of the measured C-V characteristics extracted the polynomial coefficients, which include both C_j and C_p. Table 1 presents the obtained values of the polynomial coefficients. The C-V characteristics of the measured data, the standard CV model, and the polynomial model are presented in Fig. 3. The relative error between the measurement and the two models are depicted as an inset in Fig. 3. The measured data and polynomial model have excellent agreement with a maximum relative error of 2.4$\%$. In contrast to the polynomial model, the standard CV model has large discrepancies compared to the measured data with a maximum relative error of 9.9$\%$. In the comparison, the standard CV model utilizes the datasheet parameters. However, even with optimization of the parameters, it was not possible to have a good agreement between the model and the measured data for the full bias range. When the C-V characteristics are not accurately modeled it will affect the accuracy of the nonlinear behavior, which will be discussed in Section V. In this work, the polynomial varactor model (9) was employed due to its superior C-V fit for highly nonuniform varactor-diodes.

Figure 3. The C-V characteristic of the measured data, polynomial model and the standard C_V model. The inset depicts the relative error between the measured data and the two models.

The series inductance was determined from the frequency-dependency of the measured C-V. From measured Z ₁₂ and $C_V(V_R)$ extracted at low frequency, $L_s = 1.51$ nH was obtained using a least-square fit of the imaginary part of (7) versus frequency for each bias voltage, which can be compared to the datasheet value of 0.7 nH. The larger extracted value is due to the inductance from the pads connecting the varactor. At higher frequencies, L_s has a greater influence on Im(Z ₁₂) and to adequately model the nonlinear behavior this influence should be modeled to at least the frequency of the third harmonic. Figure 4 depicts the Im(Z ₁₂) for the second and third harmonic, corresponding to 3 GHz and 4.5 GHz, respectively. The second harmonic is inductive at the lower range of V_R, and the third harmonic is inductive over the full range of V_R.

Figure 4. Modeled and measured Im$(Z_{12})$ for the second harmonic (3 GHz) and third harmonic (4.5 GHz).

Lastly, the series resistance was found from Re$(Z_{12})$. The measured resistance versus bias is depicted in Fig. 5. At low frequency, the measurement is noisy, and at higher frequency the resistance increases due to the skin effect and distributed effects in the varactor. The resistance was obtained by finding the average for each frequency and then calculating the average of those averages. The frequencies were limited to 1.5–2.5 GHz to avoid the measurement noise, skin effect, and distributed effects at high frequencies. The obtained R_s was 1.49 Ω, which is close to the datasheet value of 1.2 Ω.

Figure 5. Real part of the measured varactor impedance.

Realization of loaded-line phase shifter

The design parameters of a loaded-line phase shifter are the loading capacitance C ₀, the unloaded impedance Z ₀, and the physical length θ ₀. The loaded-line phase shifters were designed with two different unit cells differentiated by the effective electrical length θ_e. Both unit cells have the same configuration, which is a T-unit cell that is composed of a grounded coplanar waveguide (CPWG) and a shunt varactor-diode located in the center, as illustrated in Fig. 6. The CPWG was manufactured on the substrate Rogers RO4350 with $\epsilon_r = 3.66$. The unit cells were designed to have $Z_e = 50$ Ω and two different θ_e at the center of the tuning range and at the design frequency of 1.5 GHz. The tuning range was selected to be from $V_R = 3$ V to $V_R = 8$ V. The lower limit of V_R was selected because of two reasons. Firstly, there is a risk that the varactor becomes forward-biased when V_R is close to zero because of the addition of the RF voltage swing. Secondly, the phase shifter’s insertion loss (IL) increases significantly when $V_R \lt 3$ V, which makes the phase shifter unsuitable in that bias range. The upper limit was selected to avoid the breakdown region, and a larger limit only resulted in minimal gain in terms of tuning range. In Fig. 7, the simulated phase $\phi(S_{21})$ and Z_e are presented for the two unit cells at the center of the tuning range $V_R = 5.5$ V. The shorter unit cell has a θ_e = 57.7^∘ at the design frequency and a $Z_0 =$ 100 Ω. The longer unit cell has a θ_e = 66.4^∘ at the design frequency and a $Z_0 =$ 90 Ω. All dimensions of the two unit cells are presented in Fig. 6.

Figure 6. Illustration of the unit cell configuration composed of the unit cell and the thru lines. The dimensions of the unit cell with $\theta_e = 57.7^\circ$ are l = 10.1 mm, w = 0.31 mm, and g = 2.34 mm. The dimensions of the unit cell with $\theta_e = 66.4^\circ$ are l = 13.14 mm, w = 0.4 mm, and g = 2.29 mm. The dimensions of the thru line are $l_t = 8 $ mm, $w_t = 1.183 $ mm, and $g_t = 1.9 $ mm.

Figure 7. The simulated effective characteristic impedance and the effective electrical length for the two designed unit cells at $V_R = 5.5$ V.

With the two designed unit cells, six phase shifters were fabricated with 1, 5, and 10 unit cells, which have the purpose to validate the polynomial varactor model and to compare the FOM and linearity with respect to unit cell length and number of unit cells. The fabricated phase shifters are depicted in Fig. 8, where one can see that the input and output consist of a coaxial connector and a thru line. To de-embed the effect of the coaxial connector and the thru line, a thru-reflect-line (TRL) was designed as described in [Reference Engen and Hoer19], and the TRL design is depicted in Fig. 9. Three lines were fabricated to cover the frequency range from 40 MHz to 4 GHz.

Figure 8. The fabricated phase shifters with 1, 5, and 10 unit cells.

Figure 9. The fabricated thru-reflect-line circuits. The reflect is generated with an open circuit. Three lines were fabricated with line lengths of 18 mm, 83.3 mm, and 386.7 mm.

Phase shifter performance

The implemented phase shifters have been measured using a N5222A PNA Microwave Network Analyzer (Fig. 12) and simulated in ADS. The simulated and measured IL, phase shift, and return loss (RL) were compared to validate the polynomial varactor model. The results of the phase shifters with different unit cell lengths share similar results that are summarized in Table 2. Figure 13 depicts the IL, phase shift, and RL for the phase shifters with a unit cell length of 57.7^∘. The shape and trends are similar for the 66.4^∘ phase shifter. For all phase shifters, the measured data agree well with the results from the model. The measured IL for the phase shifters with 5 and 10 unit cells are larger than the simulated IL, which may be attributed to higher metal loss due to deviating conductivity and higher surface roughness in the fabricated phase shifters. There is also some deviation in phase shift after 2 GHz between simulated and measured results, where the phase shifter becomes more dispersive. Figure 14 depicts $\Delta\phi$ between V _Rmin = 3 V and V _Rmax = 8 V. Figure 15 depicts the FOM over frequency for V _Rmax. The measured result has unrealistic values at low frequency due to limited precision in vector network analyzer (VNA)calibration, which greatly impacts the low IL. The measured FOM is lower than the simulated FOM after 0.5 GHz because of the larger measured IL. Table 2 shows that the measured $\Delta\phi$ at 1.5 GHz is greater for the phase shifters with the longer unit cell length of 66.4^∘. This is to some extent surprising as the phase shift is expected to increase as the varactor inclusion factor increases. However, a longer unit cell is also more dispersive and the dispersion accelerates the phase shift, as can be seen in Fig. 13. The FOM is larger for the phase shifters with the shorter unit cell length of 57.7^∘ due to lower IL. Consequently, the phase shifters with the shorter unit cell present the best performance in terms of both FOM and linearity. In Section VI, it will be investigated how the performance can be further optimized by tuning the unit cell length and adapting the varactor-capacitance value.

Table 2. Summary of the measured $\Delta \phi$, FOM, IL, RL at 1.5 GHz, and the $IIP3$ at 1.6 GHz for all fabricated phase shifters. The IL is presented when $V_{\textrm{Rmin}} = 3 $ V, which gives the largest IL. The RL is selected at $V_R = 5$ V. The $IIP3$ is selected at $V_R = 5.5$ V

Figure 12. S-parameter measurement setup. Note that the polarity of the DC supply output is reversed to achieve a negative bias over the varactor.

Figure 13. The simulated and measured S-parameter results of the realized phase shifters with a unit cell length of 57.7^∘.

Figure 14. The differential phase shift between V _Rmin = 3 V and V _Rmax = 8 V for the phase shifters with a unit cell length of 57.7^∘.

Figure 15. FOM at V _Rmax = 8 V for the phase shifters with a unit cell length of 57.7^∘.

Phase shifter IMD

To examine the linearity of the fabricated loaded-line phase shifters a two-tone measurement was carried out, and the measurement setup is shown in Fig. 16. The measurement was performed with a network analyzer Keysight PNA-X N5247B (PNA) that both generated the two fundamental signals and measured the IM with the swept IMD measurement type enabled. Two sources generate the two fundamental signals internally of the PNA, and the two signals exit two different ports. Each channel is connected to a low-pass filter (DC-2250 MHz) to suppress any harmonics generated in the sources. The low-pass filter is connected to an isolator to prevent leakage between the channels and to suppress any reflections. After the isolators, the two signals are combined in a 6-dB combiner that is connected to a bias-T, which is connected to the DUT. The DUT is then connected to a third PNA port that measures the IM generated in the DUT. The measurement setup’s noise floor was measured to −115 dBm, and the residual IM was below this level.

Figure 16. Two-tone measurement setup for forward IM (a) measurement setup (b) illustration. The fundamental signals are generated by the PNA internally, and the IM is measured with the same PNA at a third port in swept IMD measurement mode.

The IM ₃ was simulated and measured with an input power swept from −18 dBm to 1.6 dBm. A comparison of the phase shifters’ linearity is presented in Table 2 in terms of the $IIP3$. The $IIP3$ was obtained by extrapolating the measured input power and IM ₃. With more unit cells the phase shifters become more nonlinear and the $IIP3$ decreases. The results also show that the phase shifters with a shorter unit cell length have better linearity. Figure 17 shows the IM ₃ as a function of V_R at 1.6 GHz, with a P _in of 1.6 dBm. The model accurately predicts the nonlinear behavior, particularly for the phase shifters with a single unit cell. There are some discrepancies between the model and the measurements for the phase shifters with 5 and 10 unit cells in the range of 3–5 V. At $V_R =$ 0 V, the IM ₃ has a maximum for a single unit cell whereas the phase shifters with 5 and 10 unit cells have a minimum. The minimum is attributed to suppression of the input signals because the measured IL > 70 dB at 1.5 GHz when $V_R = 0$ V. For a single unit cell with $\theta_e = 57.7^\circ$, the measured IL is 12.9 dB. Also, Fig. 17 presents the IM ₃ for the standard C_V model for 1 unit cell. The result shows that the standard C_V model cannot properly model the nonlinear behavior of the hyperabrupt varactor. The disagreement becomes more distinct with more unit cells added.

Figure 17. The IM ₃ for the phase shifters with unit cell length 57.7^∘ at 1.6 GHz with a $P_{\textrm{in}} = 1.6$ dBm.

Influence of unit cell length

The influence of the unit cell length on the phase shifter performance and linearity was investigated. The study was performed by reducing the unit cell length of the reference unit cell. The effect of reducing the unit cell length is an increased varactor-capacitance per unit cell length. To have a fair comparison, the varactor-capacitance per unit cell length was consistent for all different cases that were compared. This was achieved by modifying the varactor’s capacitance with the same amount of reduction of the unit cell length. However, reducing C_V will also affect the Q factor of the varactor, and therefore, the series resistance had to be modified to compensate for the change in Q factor. Figure 18 illustrates how θ ₀, C_V, and R_s are modified with the value N. As we reduce the unit cell’s length, θ ₀ and C_V are divided by N, and R_s is multiplied by N. In this study, N is chosen to have the values of 1, 2, 4, and 8, where N = 1 for the reference unit cell. When θ ₀ is divided, θ_e is not reduced with the same amount as θ ₀ due to the dispersive behavior of the unit cells. Figure 19 depicts θ_e, IL, C_V, and IM ₃ for the four different unit cells. The IL is greatly reduced with a shorter unit cell. The IM ₃ is lowered at a larger revered bias $(V_R \gt 3.5)$ V with a shorter unit cell. At a lower reversed bias, the reference unit cell has an IM ₃ similar to $\theta_0 /2$ and $\theta_0 /4$.

Figure 18. Modification of the unit cell to maintain the same capacitance per unit cell length and Q factor for all phase shifters. The reference unit cell has an $N =$ 1. The component values are L_s = 1.51 nH, R_s = 1.49 Ω, θ ₀ = 36^∘ at 1.5 GHz and V_R = 5.5 V, and the coefficients for C_V are shown in Table 1.

Figure 19. For each single unit cell (a) phase shift, (b) insertion loss, (c) varactor-capacitance, and (d) third-order intermodulation.

The phase shift from a single unit cell is seldom sufficient for real applications. Therefore, the reference phase shifter was designed with 10 unit cells. All phase shifters had the same physical length in the investigation. To obtain the same physical length as the reference phase shifter, the phase shifters with unit cell lengths of $\theta_0/2$, $\theta_0/4$, and $\theta_0/8$ had 20, 40, and 80 unit cells, respectively. In Fig. 20, $\Delta\phi$ and FOM are presented as functions of V _Rmin when V _Rmax is set to 8 V, at the fundamental frequency of 1.5 GHz. The figure shows that if the same tuning range is utilized for all phase shifters, $\Delta\phi$ is greater with a longer unit cell, and the FOM is greater with a shorter unit cell. However, with a shorter unit cell, the IL reduces and enables a larger tuning range with a larger FOM. Therefore, Fig. 20 was utilized to find the V _Rmin that generated the maximum FOM for each phase shifter. The figure shows that the phase shifters with a unit cell length of θ ₀, $\theta_0/2$, $\theta_0/4$, and $\theta_0/8$, generate the largest FOM when V _Rmin is 3 V, 2.25 V, 2 V, and 1.75 V, respectively. In Fig. 21, the differential phase shift and FOM are depicted versus frequency when V _Rmin is selected to maximize FOM. It shows that the phase shifter with a unit cell length of $\theta_0/8$ has the best FOM over the majority of the frequency spectrum and achieves the largest $\Delta\phi$ from DC to 1.7 GHz. The IM ₃ at 1.6 GHz is presented in Fig. 22. The lowest and highest IM ₃ between the phase shifters varies with V_R. The reference phase shifter has the lowest IM ₃ at low V_R, however, it obtains the largest at a V_R above 4.4 V. The phase shifters with a unit cell length of $\theta_0/4$ and $\theta_0/8$ have similar IM ₃, which is the largest at low V_R. This demonstrates that having many small nonlinear elements does not necessarily provide good linearity. The best alternative in this comparison is the phase shifter with a unit cell length of $\theta_0/2$, as it provides better linearity over the full bias range.

In summary, a phase shifter with shorter unit cells presents better phase shifter performance. In the case of IM ₃, a phase shifter with fewer longer unit cells can benefit linearity. It is a trade-off between phase shifter performance and linearity. In the comparison presented, a good trade-off would be the phase shifter with a unit cell length of $\theta_0/2$ as it has good linearity over the full bias range and a FOM = 102^∘/dB at 1.5 GHz, which is close to the phase shifter with a unit cell length of $\theta_0/8$ that had a FOM = 108^∘/dB.

Influence of varactor quality factor

The influence of the varactor’s Q factor on the phase shifter was investigated. The same reference unit cell was employed as in the study of the influence of unit cell length. The reference unit cell had a $Q_0 = 61$ at the design frequency of 1.5 GHz when $V_R = 5.5$ V. The varactor’s Q factor was modified by changing R_s. Five phase shifters were compared with the Q factors of $4Q_0$, $2Q_0$, Q ₀, $Q_0/2$, and $Q_0/4$, corresponding to series resistances of $R_s/4$, $R_s/2$, R_s, $2R_s$, and $4R_s$, respectively. These five cases were investigated for a phase shifter composed of 10 unit cells. Therefore, the phase shifters have the same physical length. The Q factor affects θ_e minimally and $\Delta\phi$ is similar for all phase shifters except when they reach the cut-off region, as depicted in Fig. 23(a). When the Q factor is increased, the IL is reduced because of the reduced losses of the varactor. Therefore, the FOM is substantially increased with a larger Q factor, as depicted in Fig. 23(b). Figure 24 shows the IM ₃ for the five phase shifters. The figure shows that a larger Q factor increases the IM ₃, which is attributed to the smaller series resistance. When R_s is reduced, the voltage swing over R_s is smaller and the voltage swing over C_V increases, increasing IMD. The results show that a larger Q factor greatly improves the phase shifter performance. However, it should be noted that there is a trade-off between low varactor loss and IMD.

Figure 20. The differential phase and FOM at 1.5 GHz when V _Rmin is varied and V _Rmax is set to 8 V, for each phase shifter with the different unit cell lengths of θ ₀, $\theta_0/2$, $\theta_0/4$, and $\theta_0/8$. The plot shows which V _Rmin generates the largest FOM for each phase shifter when $V_{\textrm{Rmax}} = 8$ V.

Figure 21. (a) Differential phase and (b) FOM when V _Rmin is selected to generate maximum FOM for each phase shifter with the different unit cell lengths of θ ₀, $\theta_0/2$, $\theta_0/4$, and $\theta_0/8$.

Figure 22. IM ₃ for each phase shifter with the different unit cell lengths of θ ₀, $\theta_0/2$, $\theta_0/4$, and $\theta_0/8$ at 1.6 GHz with a $P_{\textrm{in}} = $ 1.6 dBm.

Figure 23. (a) Differential phase shift and (b) FOM for different Q factors.

Figure 24. IM ₃ for different Q factors at 1.6 GHz with a $P_{\textrm{in}} = $ 1.6 dBm.