Determination of the impedance Z ₀

The common node impedance Z_com in an asymmetric Doherty modulation network is Z ₀/N. As depicted in Fig. 2 it is transformed from the load R _L by TL₁ with a characteristic impedance Z ₁ of

(7)$$Z_{1} = \sqrt{R_{\rm{L}}\cdot{Z_{0}\over N}}.$$

Fig. 2. Schematic of the proposed Doherty load modulation network with a $Z_{0}\cdot {\bf \xi }\ {\rm TL}_{0}$ impedance transformer.

For a classical DPA, the frequency response of Z_com is analyzed in [Reference Nikandish, Staszewski and Zhu5]. In case of a more general asymmetric topology, this expands to

(8)$$\underline{Z}_{\rm{com}} = {Z_{0}\over N} \cdot {{1 \over m} + {{\,j}} \cdot \tan( {\pi \over 2}{\,f \over f_{0}}) \over m + {{\,j}} \cdot \tan( {\pi \over 2} {\,f \over f_{0}}) }$$

with

(9)$$m = \sqrt{{Z_{0}\over N\cdot R_{\rm{L}}}}.$$

For m = 1, the frequency dependent part of (8) is canceled. This is achieved at

(10)$$Z_{0} = R_{\rm{L}}\cdot N.$$

By inserting (10) into (8) one obtains

(11)$$\underline{Z}_{\rm{com}} = R_{\rm{L}},\; $$

thus no bandwidth limiting IT is necessary and TL₁ can be omitted. If for design reasons a Z ₀ different from (10) is necessary, a broadband post matching network should be used. Several works, such as [Reference Li, Pang, Li and Zhu4, Reference Seidel, Wagner and Ellinger7], provide solutions for this task.

Main path impedance provided by a Doherty modulation network with scaled impedance transformer

The characteristic impedance of TL₀ can be chosen freely, even if Z ₀ is already defined by (10). Hence, ξ is now introduced as scaling variable. For the proposed Doherty load modulation network in Fig. 2, the impedance analysis is carried out at the output nodes of the ideal current sources as reference plane. According to (3), the extended calculation for Z_M follows:

(12)$$\underline{Z}_{\rm{M}} = {\left(Z_{0}\cdot\xi\right)^{2}\over \underline{Z}_{\rm{M, t}}} = Z_{0}\cdot\xi^{2}\cdot{N\over ( 1 + \underline{\alpha}_{\rm{t}}) }.$$

The ratio of the peak path to the main path current needs to satisfy the equation

(13)$${\vert \underline{I}_{\rm{P}}\vert \over \vert \underline{I}_{\rm{M}}\vert } = \xi \cdot ( N-1) $$

to ensure the correct ratio of I_M,t and I_P at the common node for V _in = V _in,max.

Frequency analysis of the load modulation in the main path

The previous calculations are only valid at the design frequency f ₀. However, the topology related λ/4 IT TL₀ lowers the ADPA's bandwidth independently of the main or peak amplifier bandwidth. Z_M and Z_P are real-valued at f ₀. Below and above this frequency, imaginary parts occur and subsequently the real part changes. This causes mismatch and thus a reduction in the efficiency of the amplifier. Moreover, a phase shift between the main and peak path current appears at the common node of the main and peak path, which is not compensated by the λ/4 IT at the peak amplifier input. The summation of I_M,t and I_P becomes complex-valued, thus the ratio α_t, previously defined in (1), also depends on the frequency.

To analyze the Doherty load modulation network and its impedances Z_M and Z_P in the frequency domain, the reference plane in Fig. 2 is used as input of a two-port network. The two-port equation in ABCD-parameters yields

(14)$$\left[\matrix{\underline{V}_{\rm{M}} \cr \underline{I}_{\rm{M}} }\right] = \left[\matrix{\underline{A}_{\rm{M}} & \underline{B}_{\rm{M}} \cr \underline{C}_{\rm{M}} & \underline{D}_{\rm{M}} }\right]\cdot \left[\matrix{\underline{V}_{\rm{M, t}} \cr \underline{I}_{\rm{M, t}} }\right].$$

The transmission parameters for the lossless transmission line TL₀ with Z ₀ · ξ as its characteristic impedance are

(15)$$\left[\matrix{\underline{A}_{\rm{M}} & \underline{B}_{\rm{M}} \cr \underline{C}_{\rm{M}} & \underline{D}_{\rm{M}} }\right] = \left[\matrix{\cos( {\pi\over 2}{\,f\over f_{0}}) & {{\,j}}\cdot Z_{0} \cdot \xi \sin ( {\pi\over 2}{\,f\over f_{0}}) \cr {{{\,j}}\over Z_{0} \cdot \xi} \sin( {\pi\over 2}{\,f\over f_{0}}) & \cos ( {\pi\over 2}{\,f\over f_{0}}) }\right].$$

The voltage at the common node V_com can be expressed by

(16)$$\underline{V}_{\rm{com}} = \underline{V}_{\rm{M, t}} = \underline{V}_{\rm{P}} = ( \underline{I}_{\rm{M, t}} + \underline{I}_{\rm{P}}) \cdot \underline{Z}_{\rm{com}}.$$

Inserting (16) into (14), the voltage V_M and current I_M at the main path input are defined by

(17)$$\underline{V}_{\rm{M}} = \underline{A}_{\rm{M}}\cdot ( \underline{I}_{\rm{M, t}} + \underline{I}_{\rm{P}}) \cdot \underline{Z}_{\rm{com}} + \underline{B}_{\rm{M}} \cdot \underline{I}_{\rm{M, t}}$$

(18)$$\underline{I}_{\rm{M}} = \underline{C}_{\rm{M}}\cdot ( \underline{I}_{\rm{M, t}} + \underline{I}_{\rm{P}}) \cdot \underline{Z}_{\rm{com}} + \underline{D}_{\rm{M}} \cdot \underline{I}_{\rm{M, t}}.$$

Rearranging (18) to I_M,t and inserting it into (17) yields V_M in dependency of the two input currents:

(19)$$\eqalign{\underline{V}_{\rm{M}}& = \underline{A}_{\rm{M}}\cdot\left({\underline{I}_{\rm{M}}-\underline{C}_{\rm{M}}\cdot \underline{I}_{\rm{P}}\cdot \underline{Z}_{\rm{com}}\over \underline{C}_{\rm{M}}\cdot \underline{Z}_{\rm{com}} + \underline{D}_{\rm{M}}} + \underline{I}_{\rm{P}} \right)\cdot \underline{Z}_{\rm{com}} \cr & \quad + \underline{B}_{\rm{M}} \cdot \left({\underline{I}_{\rm{M}}-\underline{C}_\rm{{M}}\cdot \underline{I}_{P}\cdot \underline{Z}_{\rm{com}}\over \underline{C}_{\rm{M}}\cdot \underline{Z}_{\rm{com}} + \underline{D}_{\rm{M}}} \right).}$$

Dividing (19) by I_M one obtains Z_M. According to (13), the ratio of the current amplitudes |I_M| and |I_P| can now be expressed as

(20)$${\vert \underline{I}_{\rm{P}}\vert \over \vert \underline{I}_{\rm{M}}\vert } = \left\{\matrix{& 0 & & 0\leq V_{\rm{in}} < {V_{\rm{in, max}}\over N} \cr & \xi\cdot\left(N-{V_{\rm{in, max}}\over V_{\rm{in}}}\right)& & {V_{\rm{in, max}}\over N} \leq V_{\rm{in}} \leq V_{\rm{in, max}}. }\right.$$

For a complex-valued peak-to-main current ratio before transformation α, a phase shift of π/2 at f ₀ between I_P and I_M has to be considered, which is provided by the λ/4 IT at the peak amplifier input:

(21)$$\underline{\alpha} = {\underline{I}_{\rm{P}}\over \underline{I}_{\rm{M}}} = \vert \underline{\alpha}\vert \cdot {e}^{-{{\,j}}\cdot( {\pi}/{2}) ( {\,f}/{\,f_{0}}) }.$$

Thus, the Doherty impedance of the main path Z_M without saturation can be described by

(22)$$\eqalign{\underline{Z}_{\rm{M}}& = \underline{A}_{\rm{M}}\cdot\left({1-\underline{C}_{\rm{M}}\cdot \underline{\alpha}\cdot \underline{Z}_{\rm{com}}\over \underline{C}_{\rm{M}}\cdot \underline{Z}_{\rm{com}} + \underline{D}_{\rm{M}}} + \underline{\alpha} \right)\cdot \underline{Z}_{\rm{com}} \cr & \quad + \underline{B}_{\rm{M}} \cdot \left({1-\underline{C}_{\rm{M}}\cdot \underline{\alpha}\cdot \underline{Z}_{\rm{com}}\over \underline{C}_{\rm{M}}\cdot \underline{Z}_{\rm{com}} + \underline{D}_{\rm{M}}} \right).}$$

To take the saturation of the main amplifier current source into account, a maximum drain-source voltage V _DS,M,max is defined based on I _D,M,max and Z_M(α_t = 0) at f ₀:

(23)$$V_{\rm{DS, M, max}} = I_{\rm{D, M, max}} \cdot Z_{0} \cdot \xi^{2}.$$

The behavior considering saturation is conditioned with

(24)$$\underline{V}_{\rm{M}} = \left\{\matrix{& \underline{V}_{\rm{M}} & & \vert V_{\rm{M}}\vert \leq V_{\rm{DS, M, max}} \cr & V_{\rm{DS, M, max}} & & \vert V_{\rm{M}}\vert > V_{\rm{DS, M, max}}. }\right.$$

In case of |V _M| > V _DS,M,max, the ideal voltage-controlled current source turns into an ideal voltage-controlled voltage source. To describe Z_M,sat for this case, (19) is used with V_M equal to V _DS,M,max to express the saturation current as

(25)$$\eqalign{\underline{I}_{\rm{M, sat}}& = {\left(V_{\rm{DS, M, max}}-\underline{A}_{\rm{M}}\right)\cdot\left(\underline{C}_{\rm{M}}\cdot\underline{Z}_{\rm{com}} + \underline{D}_{\rm{M}}\right)\over \underline{A}_{\rm{M}}\cdot\underline{Z}_{\rm{com}} + \underline{B}_{\rm{M}}} \cr & \quad + {\underline{Z}_{\rm{com}} \cdot \underline{I}_{\rm{P}} \cdot \left(\underline{A}_{\rm{M}} \cdot \underline{C}_{\rm{M}} \cdot \underline{Z}_{\rm{com}} + \underline{B}_{\rm{M}}\cdot \underline{C}_{\rm{M}}\right)\over \underline{A}_{\rm{M}}\cdot\underline{Z}_{\rm{com}} + \underline{B}_{\rm{M}}}.}$$

Finally, the Doherty impedance for the main path with saturation results in

(26)$$\underline{Z}_{\rm{M, sat}} = \left\{\matrix{ \underline{Z}_{\rm{M}} & \vert V_{\rm{M}}\vert \leq V_{\rm{DS, M, max}} \cr {V_{\rm{DS, M, max}}\over \underline{I}_{\rm{M, sat}}} & \vert V_{\rm{M}}\vert > V_{\rm{DS, M, max}} }\right..$$

Fig. 3 illustrates the contours of Z_M,sat for three different values of ξ by sweeping the input voltage from back-off to maximum level, as well as the frequency from 0.5 · f ₀ to 1.5 · f ₀. The crossing of the real axis occurs at f ₀. On the left side, the saturation causes the straightening of the curves due to the limited magnitude of Z_M,sat. For the input voltage

(27)$$V_{\rm{in, \xi}} = \xi \cdot V_{\rm{in, max}},\; $$

Z_M,sat is solely real-valued over the frequency and equal to the characteristic impedance of TL₀. Thus, a maximum broadband matching is reached at this point, which can be defined via ξ. In Fig. 3, these points are highlighted respectively.

Fig. 3. Curves of the Doherty impedances at the reference plane of the main path Z_M,sat versus frequencies from 0.5 · f ₀ to 1.5 · f ₀ for different values ξ and N = 2.5 while sweeping the input voltage V _in with input voltages V _in,ξ for a maximum broadband matching highlighted.

Frequency analysis of the load modulation in the peak path

For the peak path, similar considerations can be made. Taking (16) and (18) into account, the peak amplifier Doherty impedance Z_P can be derived. Here, the saturation effect for the peak amplifier can be neglected, since the chosen characteristic impedance for TL₁ of R _L · N leads to a coherent addition of the currents I_M,t and I_P. Thus, the highest impedance or voltage magnitude always occurs at f ₀. The saturation of the main amplifier however affects the peak path, which is why a distinction between I_M and I_M,sat has to be considered for the calculation Z_P given by

(28)$$\underline{Z}_{\rm{P}} = {\underline{V}_{\rm{P}}\over \underline{I}_{\rm{P}}} = \left({{\underline{I}_{\rm{M/M, sat}} \over \underline{I}_{\rm{P}}}-C_{\rm{M}}\cdot \underline{Z}_{\rm{com}}\over C_{\rm{M}}\cdot \underline{Z}_{\rm{com}} + D_{\rm{M}}} + 1\right)\cdot\underline{Z}_{\rm{com}}.$$

In Fig. 4, the impedance curves for Z_P are shown for the same conditions as for Fig. 3. The effect of saturation of the main amplifier is less pronounced for Z_P. For input voltages below V _in,max/N, Z_P approaches infinity. With increasing V _in, either the real (ξ = 1) or the imaginary (ξ = 1/N) part of Z_P increases. Here, the maximum broadband matching at V _in,ξ becomes also evident.

Fig. 4. Curves of the Doherty impedances at the reference plane of the peak path Z_P versus frequencies from 0.5 · f ₀ to 1.5 · f ₀ for different values ξ and N = 2.5 while sweeping the input voltage V _in.

The performance for signals with a larger bandwidth depends mostly on the broadband matching properties. However, the ξ-scaled IT is only matched at V _in,ξ. Simultaneous matching at back-off and peak level is not achieved. To find the best tradeoff, the impact on the drain efficiency of the ADPA will be examined in the following segment.

Frequency analysis of the drain efficiency

Given the preliminary discussion, an ADPA's DE can be considered. With amplifiers biased in class B, the ratio of RF output power to DC power consumption for Fig. 2 follows:

(29)$$DE = {\pi\over 4} \cdot {\vert \underline{I}_{\rm{M}}\vert ^{2}\cdot{\rm Re}( \underline{Z}_{\rm{M, sat}}) + \vert \underline{I}_{\rm{P}}\vert ^{2}\cdot{\rm Re}( \underline{Z}_{\rm{P}}) \over \vert \underline{I}_{\rm{M}}\vert \cdot V_{\rm{DS, M, max}} + \vert \underline{I}_{\rm{P}}\vert \cdot V_{\rm{DS, P, max}}}.$$

The DE curve with its two efficiency peaks at back-off and maximum output power level is now derived for different frequencies. For broadband signals, this consideration is necessary to reach a high overall efficiency. As illustrated in Fig. 5, the efficiency trajectories beside f ₀ are affected by the frequency-dependent Doherty impedances Z_M,sat and Z_P. For ξ = 1/N and ξ = 1, they only reach one efficiency peak at V _in,ξ. With $\xi = 1/\sqrt {N}$, V _in,ξ is between back-off and maximum input level, so these curves have a local maxima in between. For a classical Doherty load modulation network where ξ = 1 and N = 2.5, the back-off DE at f/f ₀ = 1.25 is just 42% and further drops to 21% at f/f ₀ = 1.5. Otherwise, a high efficiency is reached at maximum input level due to maximum broadband matching.

Fig. 5. Drain efficiency DE versus normalized input voltage V _in beside f ₀ for N = 2.5 and different values of ξ.

Drain efficiency depending on probability density function

In order to estimate the broadband efficiency, a PDF-weighted input signal is used. The overall PDF-weighted efficiency DE _PDF,B within a bandwidth

(30)$$B = f_{\rm{max}}-f_{\rm{min}}$$

can be defined as

(31)$$DE_{\rm{PDF, B}} = {1\over B}\cdot\int_{0}^{1}\int_{\,f_{\rm{min}}}^{\,f_{\rm{max}}} DE( V_{\rm{in}},\; f) \cdot PDF( V_{\rm{in}}) {d}f\,{d}V_{\rm{in}}.$$

To analyze the previous load modulation networks, a Rayleigh distribution defined by

(32)$$PDF_{\rm{Ray}}( V_{\rm{in}}) = {V_{\rm{in}}\over \sigma^{2}}\cdot e ^{-V_{\rm{in}}/2\sigma^{2}}$$

is utilized as an example.

With $\sigma = 1/N\cdot \sqrt {2/\pi }$, the expected value arises at OBO which meets the desired PAPR. As stated in (31), the PDF is considered only for the input voltage, while the distribution is uniform over frequency. Fig. 6 compares DE_PDF,B for the three different bandwidths, while ξ is swept. For the used PDF with a PAPR of 8 dB, the highest efficiency is reached at ξ = 0.4, which corresponds to ξ = 1/N. The optimum becomes all the more obvious with increasing bandwidth. Moreover, to ensure maximum efficiency, V _in,ξ should meet the expected value. This principle was also found to be true for signals with an uniform PDF. The estimation of the system efficiency should be based on the PDF of the signal to be transmitted and not exclusively on DE curves. This approach should already be considered in the design process.

Fig. 6. Averaged drain efficiency versus ξ for Rayleigh-distributed signals of different relative bandwidths with N = 2.5, Z ₀ = R _L · N.

Optimum load determination with intrinsic node method

Beside the common load-pull method to determine the optimum load for a PA, the current and voltage waveforms at the current source plane of the active device can be used [Reference Tasker and Benedikt8]. Since the theoretical considerations of the modulation network are carried out at the current source plane, the parasitics of the package, landing pads, and bias network have to be taken into account for the matching procedure. Fig. 8 illustrates the impedances at different reference planes as well as the two-port blocks transforming the impedances between these planes. Fortunately, the used transistor model allows to simulate current and voltage waveforms of the intrinsic drain node. According to the desired output power and bias conditions, a real-valued load line R _OPT,int is applied to its output characteristics.

Fig. 8. General schematic of the packaged active device with parasitic and matching network block.

To determine the optimal intrinsic load for the main amplifier R _OPT,M,int and for the peak amplifier R _OPT,P,int, the transistors are biased in a deep class AB with V _Bias,M/P = −2.9 V. According to the advantages described in [Reference Grams, Seidel, Stärke, Wagner and Ellinger6], an asymmetric drain biasing of V _DD,M = 18 V and V _DD,P = 28 V is used. The main PA has to reach an output power of P _out,M,OBO = 34 dBm at OBO (α = 0) and P _out,M,PEP = 38 dBm at peak envelope power (PEP, α = N − 1), while the peak PA is turned off at OBO and delivers a P _out,P,PEP = 40 dBm at PEP. Thus, one obtains

(33)$$R_{\rm{OPT, M, int}}( \underline{\alpha} = 0) = {49.5}\, {\Omega}$$

at OBO and

(34)$$R_{\rm{OPT, M, int}}( \underline{\alpha} = N-1) = {32.4}\, {\Omega}$$

at PEP for the specific device and bias conditions. The peak amplifier R _OPT,P,int yields

(35)$$R_{\rm{OPT, P, int}}( \underline{\alpha} = N-1) = {33.7}\, {\Omega}$$

at PEP.

Based on these values, the impedance at the device/bias plane is varied to identify the optimum external load Z_OPT,ext, which transforms to R _OPT,int at the intrinsic node. The corresponding impedance characteristics for the main amplifier between OBO and PEP and for the peak amplifier at PEP are shown in Fig. 9. R _OPT,int,M and R _OPT,int,P are independent of frequency and located on the real axis. Depending on the frequency, they are transformed from the current source plane to the device/bias plane to Z_OPT,ext,M and Z_OPT,ext,P, respectively.

Fig. 9. Optimum intrinsic load R _OPT,int and external impedance Z_OPT,ext derived from intrinsic node method for main amplifier with α = (0, …, N − 1) and peak amplifier with α = N − 1 over the frequency range from 3.2 GHz to 4.0 GHz.

Output matching network design

The OMN of the main amplifier has to transform the Doherty impedance Z_M to the previously determined impedances Z_OPT,M,ext. According to (12), this OMN depends on the modulation index α and the scaling factor ξ. To simplify the design procedure and keep the complexity of the OMN moderate, Z_OPT,M,ext at the center frequency of 3.6 GHz is used with α = 0 and α = N − 1, respectively. This impedance has to be transformed from Z_M(α, ξ) as specified in Table 1.

Table 1. Values for the main amplifier's Doherty impedance Z_M with N = 2.5, Z ₀ = R _L · N, and f = 3.6 GHz

The OMN is realized as double-cascaded transmission line open-stub design, which avoids the use of lossy SMD components. An optimization algorithm is used to determine the optimal dimensions meeting the upper defined transforming conditions for each value of ξ.

The design of the peak amplifier's OMN, which transforms its Doherty impedance Z_P to Z_OPT,P,ext, is less complex. The fixed matching is independent of α and ξ. For the operation below the OBO, the peak amplifier is turned off and should behave as an open circuit at the common node connection. However, this is prevented by the capacitive off-state output impedance of a HEMT. To counteract this, RF shorted-stubs at the landing pad of the drain terminal and the offset line technique [Reference Kim9] were used to push the off-state-impedance of the peak amplifier toward the infinity region. These techniques are a further limiting aspect of an efficient broadband DPA operation due to their frequency dependence. However, the comparability for different values of ξ is maintained due to an identical peak amplifier design. The optimal external impedance at 3.6 GHz is determined with Z_OPT,P,ext = (11 − j · 13) Ω. Using (4), this impedance has to be transformed from Z_P = 83.3 Ω.

Input matching network design

For the main amplifier's input matching, a tradeoff between high efficiency and gain in the targeted bandwidth was found at an input impedance of (8 − j · 35) Ω with its gate bias set to V _Bias,M = −2.9 V. Due to the class C biasing of the peak amplifier with V _Bias,P = −4.5 V and a different optimum output impedance, the optimum input impedance is (8 − j · 25) Ω. As shown in Fig. 7, both input matching networks are realized in similar element combinations with minor differences in their dimensions. The 100 Ω resistors in the gate biasing paths ensure unconditional stability.

The λ/4 input delay line in the peak path and the power divider at the input are combined by using the 3 dB hybrid coupler XC3500P-03S by Anaren. It enables a constant 90^° phase shift within a bandwidth from 3.3 GHz to 3.85 GHz leading to a more robust performance versus frequency. Moreover, this SMD component is much smaller than an equivalent microstrip line solution.

Large signal simulation for main amplifier

Fig. 10 depicts the simulated large signal performance of the designed main amplifiers including their input and output networks. To demonstrate the influence of the load modulation network, it is necessary that the different main amplifiers achieve as equal a performance as possible. Within the targeted frequency range of 3.4 GHz to 3.8 GHz, the operating power gain G _P and power-added efficiency (PAE) of ξ = 1/N and $\xi = \sqrt {1/N}$ are almost identical. The main amplifier with ξ = 0.8 has about 0.5 dB less gain at 3.8 GHz but achieves a higher PAE performance at OBO and PEP. Outside the operating frequency, the deviations increase slightly.

Fig. 10. Simulated PAE and G_P versus frequency at OBO (P _out,M,OBO = 34 dBm) and PEP (P _out,M,PEP = 38 dBm) for main amplifiers with ξ = 1/N, $1/\sqrt {N}$ and 0.8.

Further design aspects

To simulate the design more accurately, a parasitic inductor of 50 pH is added to the simulation test bench at the source node of the transistor. It lowers the gain performance and should be kept as low as possible. To support this, a copper plate with a cavity was manufactured, where the source plate of the transistor is plugged in. In addition, mechanical stability and cooling is provided.

For the input matching network and DC blocking, high-Q multilayer ceramic capacitors GJM0335C1E2R2WB0 (input matching and DC block) and GJM0335C2A4R9BB01 (output DC block) by Murata were used. A small 0201 (0603 metric) package size with low inductive parasitics is required to ensure the operation below self resonance frequency.

Small signal measurements

The scattering parameters of the three ADPAs were measured and compared with the simulated behavior. Since the peak amplifier is biased in class C mode, it is not active for the small signal measurement. Thus, this measurement mostly reflects the main amplifier performance. Fig. 12 illustrates the forward gain S _21,dB and the input reflection coefficient S _11,dB for the simulated and measured ADPAs. For ξ = 1/N, the measured small signal bandwidth and gain have the highest value. It reaches a maximum gain of 12.3 dB at 3.6 GHz and a 3 dB bandwidth of 700 MHz. The simulated deviation of S _21,dB between ξ = 1/N and ξ = 0.8 is about 0.5 dB. For the measurement, it increases to 1.5 dB. One possible reason is better matching of ξ = 1/N at low input levels, which is also advantageous for process variations. Furthermore, a larger deviation can be observed between 4 GHz and 5 GHz where S _11,dB is higher than −5 dB. The resonance might be caused by the cavity in the copper plate, but it is outside the frequency range of interest.

Fig. 12. Measured ($\xi = ( 1/N,\; 1/\sqrt {N},\; 0.8$)) and simulated (ξ = 1/N) forward gain S _21,dB and input reflection coefficient S _11,dB versus frequency of the designed ADPAs.

Large signal measurements

To measure the output power, the PAE and the large signal behavior of the ADPAs, single tone signals were applied. The input power was swept up to 33 dBm for frequencies ranging from 3.0 GHz to 4.2 GHz. The achieved PAE and operating power gain G _P performances versus P _out at 3.4 GHz, 3.6 GHz, and 3.8 GHz are shown in Fig. 13. The measured results coincide well with the simulation. In terms of G _P as well as PAE, the amplifier with ξ = 1/N achieves the best performance. Although advantageous in theory, $\xi = 1/\sqrt {N}$ and ξ = 0.8 do not exhibit the expected broadband matching for output powers above the OBO.

Fig. 13. Measured and simulated power-added efficiency and operating power gain over output power P _out at 3.4 GHz, 3.6 GHz, and 3.8 GHz for ADPAs with ξ = 1/N, $1/\sqrt {N}$, and 0.8.

Since the major investigation was done for broadband performance, the measured PAE and G _P are plotted over frequency in Fig. 14. Here, three output power levels (34 dBm, 38 dBm, 42 dBm) were selected. For P _out = 34 dBm, representing the OBO as well as the V _in,ξ of ξ = 1/N, the respective ADPA has the highest PAE over the entire bandwidth. Between 3.4 GHz and 3.8 GHz, a PAE of around ${45}\%$ was measured for ξ = 1/N. At 3.2 GHz the PAE difference between ξ = 1/N and ξ = 0.8 was around ${10}{\% }$. For P _out of 38 dBm, which corresponds to V _in,ξ for $\xi = 1/\sqrt {N}$, the ADPA with ξ = 1/N still has the highest PAE. Especially in the frequency range from 3.1 GHz to 3.7 GHz, a constant difference of about ${9}{\% }$ compared to ξ = 0.8 can be observed. For the PEP output power of 42 dBm, the PAE curves of ξ = 1/N and $\xi = 1/\sqrt {N}$ are very similar and range from 57% to ${63}{\% }$ in the frequency band between 3.5 GHz and 4.0 GHz. The ADPA with ξ = 0.8 achieves P _out = 42 dBm only between 3.7 GHz and 3.8 GHz. Within this 200 MHz bandwidth, it even has ${5}{\% }$ less PAE of ${58}{\% }$. For frequencies that are not within this range, its G _P drops below 9 dB. Hence, an output power of 42 dBm could not be measured here.

Fig. 14. Measured operating power gain G _P and power-added efficiency of different output power levels P _out over frequency for the ADPAs with ξ = 1/N, $1/\sqrt {N}$, and 0.8.

Table 2 compares the measured large signal performance of the three measured ADPAs. Since the stand-alone main PAs operate similarly, the performance difference of the ADPAs results from the ξ-dependent modulation network. Compared to ξ = 0.8, ξ = 1/N and $\xi = 1/\sqrt {N}$ achieve a larger bandwidth, higher gain and PAE. Overall, ξ = 1/N has the best performance.

Table 2. Measured large signal performance comparison between ADPAs with different values of ξ.

Possible reasons for the disagreement between the theory of section “Analysis of the asymmetric Doherty modulation network with a scaled impedance transformer” and the measurement results are losses of gain and bandwidth in the OMNs and impedance mismatch caused by process variations. Based on the Doherty impedance for the main amplifier Z_M mentioned in Table 1, an impedance transformation ratio of 12.3 (α = 0) and 2 (α = N − 1) for ξ = 0.8 is needed. For ξ = 1/N, the impedance transformation ratio is 6.2 (α = 0) and about 1 (α = N − 1), which makes it more robust against process deviations and model inaccuracies. A similar design on a thicker substrate (e.g. 512 μm) or different ε_r is suggested here to realize microstrip lines with higher characteristic impedances by wider, less process sensitive conductor paths.

Power-added efficiency in dependency of the probability density function

To benchmark the ADPAs, the averaging method with PDF weighting is used, as it was demonstrated in section “Drain efficiency depending on probability density function”. Now the PAE is used instead of the DE as averaged value, which includes the gain performance of each amplifier. To compare all three ADPAs, the peak output power is lowered by 1 dB to 41 dBm with an observed bandwidth of 400 MHz reaching from 3.4 GHz to 3.8 GHz. This corresponds to a relative bandwidth of 11%. By lowering the peak output power by 2 dB to 40 dBm, a broader bandwidth of 900 MHz (3.2 GHz to4.1 GHz) can be used. Hence, the calculation of the averaged PAE is done for a fractional bandwidth of 25%. The results are shown in Table 3 with the highest PAE _PDF,B for ξ = 1/N for both cases.

Table 3. Averaged power-added efficiency for Rayleigh-distributed signals with N = 2.5 at (a) P _out,peak = 41 dBm, f _min = 3.4 GHz, f _max = 3.8 GHz and (b) P _out,peak = 40 dBm, f _min = 3.2 GHz, f _max = 4.1 GHz.

Using the initially specified peak output power P _out,peak = 42 dBm within a 400 MHz bandwidth from 3.5 GHz to 3.9 GHz a PAE _PDF,B of ${38.8}\%$ for ξ = 1/N can be achieved.

Power-added efficiency with modulated signals

In order to gain a more operation-related performance, comparison of the ADPAs measurements with modulated signals was carried out. The utilized baseband signal with a bandwidth of 50 MHz, a 256QAM modulation scheme and an EUTRA/LTE baseband filter leads to a PAPR of 7.9 dB. These baseband specification was chosen as example for a 5G signal transmission scenario. The PAE was measured for carrier frequencies swept from 3.425 GHz to 3.775 GHz, while keeping the average output level around 32.5 dBm. The measurement results are shown in Fig. 15. Here it becomes evident that the ADPA with ξ = 1/N achieves the highest PAE for carrier frequencies higher than 3.7 GHz. Furthermore, this ADPA version has the highest PAE performance of ${41}{\% }$, as averaged over the measured frequency range. The ADPAs with $\xi = 1/\sqrt {N}$ and ξ = 0.8 reach a slightly lower averaged PAE of 40% and ${39}{\% }$, respectively. These results also confirm the trend calculated in the previous subsection “Power-added efficiency in dependency of the probability density function”.

Fig. 15. Measured power-added efficiency and averaged output power for modulated baseband signals with a 50 MHz bandwidth, a 256QAM modulation scheme and an EUTRA/LTE baseband filter over carrier frequency for the ADPAs with ξ = 1/N, $1/\sqrt {N}$, and 0.8.