System concept

In this paper, a concept for a low-cost THz frequency-modulated continuous-wave (FMCW) radar sensor is presented, that is based on a fully integrated FMCW $0.48\,\mathrm{THz}$ radar transceiver MMIC [Reference Starke, Wittemeier, Vogelsang, Sievert, Erni, Rennings, Rucker and Pohl26] and a dielectric lens for antenna directivity and measurement range improvements.

A block diagram of the presented MMIC architecture is depicted in Fig. 2. A photograph of the manufactured MMIC is shown in Fig. 1. The circuit blocks previously described are shown in an overlay on the micrograph. The MMIC’s dimensions are $2130 \, \mu \mathrm{m}$ by $900 \, \mu \mathrm{m}$ with a power consumption of $877 \, \,\mathrm{mW}$ at a supply voltage of $3.3 \,\mathrm{V}$.

Figure 1. Photograph of the developed transceiver MMIC. The signal generation up to $240\,\mathrm{GHz}$ is depicted on the left of the figure(VCO, X2, Divider). On the top right, the transmit path is shown (PA, X2, Tx Antenna). The receive path can be seen on the bottom right (PA, IQ, SHM, Rx Antenna). This highly integrated $0.48\,\mathrm{THz}$ transceiver is realized on an MMIC with an area of just $1.92\,\mathrm{mm}^{2}$.

Figure 2. Block diagram of the developed transceiver MMIC.

In contrast to other FMCW radar sensors in the sub-THz and THz spectrum, which use external signal generation [Reference Simic, Guo and Reynaert13, Reference Mangiavillano, Kaineder, Aufinger and Stelzer17, Reference Statnikov, Öjefors, Grzyb, Chevalier and Pfeiffer27–Reference Yi, Wang, Chen, Wang, Grajal and Han30], we developed a fully integrated sensor. The frequency stabilization and chirp generation, performed by a phase-locked loop (PLL), were omitted from the fully integrated approach for several reasons. A fully programmable PLL design would have added a tremendous amount of complexity to the MMIC design and would have to be based on the simulation results of the oscillator. Furthermore, the loop filter of an integrated PLL would need to be placed on the frontend PCB due to the large component values. Hence, an external PLL on the front end is much more flexible, as it can be optimized after fabrication and measurement of the radar MMIC. An integrated voltage-controlled oscillator (VCO) at a quarter of the targeted output frequency of $480\,\mathrm{GHz}$ generates the LO signal and can be tuned to modulate the output frequency.

For frequency stabilization by the PLL, a by-16 frequency divider lowers the $120\,\mathrm{GHz}$ output signal of the VCO down to approx. $7.5\,\mathrm{GHz}$ which, allows the use of commercial PLL components [31].

A Gilbert-cell-based frequency doubler doubles the oscillator’s frequency before the signal is split into the transmit (Tx) and receive (Rx) path. A bistatic approach was chosen for this radar MMIC as it relaxes the requirements regarding the receive mixer, as there is no direct coupling from the Tx into the Rx path, as no directional coupler is used between the transmitter and receiver. In both paths, the signal is amplified by power amplifiers (PAs) to drive the subsequent building blocks of the transceiver.

The Tx signal is frequency doubled again by a push–push frequency doubler that creates the $0.48\,\mathrm{THz}$ output signal. As push-push doublers convert a differential input signal to a single-ended output signal, a single-ended patch antenna is used as Tx antenna.

In the Rx path, the amplified signal at half of the output frequency is converted to quadrature signals by microstrip-based branchline couplers (IQ) and then used to drive a subharmonic down-conversion mixer (SHM). As the subharmonic mixer has a differential RF input, a differential patch antenna can be used for signal reception.

As the signal generation of this sensor is integrated into the MMIC and no external LO signals need to be routed on the front end, the highest frequency of a signal connected to the MMIC is the approx. $ 8\,\mathrm{GHz}$ output of the frequency divider. This enables using low-cost FR4 printed circuit board (PCB) material for the front end to create a low-cost THz radar sensor (similar to [Reference Thomas, Bredendiek and Pohl22]). Furthermore, a low-cost polytetrafluoroethylene (PTFE) dielectric lens was developed to enhance the antenna directivity of the antennas on the MMIC and to shield the MMIC and bond wires from external environmental influences.

MMIC design

In this section, the separate building blocks of the fully integrated $0.48\,\mathrm{THz}$ FMCW radar MMIC are detailed, as elaborated in Section “System concept”, and measurement results are discussed.

The radar transceiver discussed in this paper was manufactured in a development lot of the 130-nm SiGe BiCMOS technology SG13G3 from IHP (based on [Reference Heinemann, Rücker, Barth, Bärwolf, Drews, Fischer, Fox, Fursenko, Grabolla, Herzel, Katzer, Korn, Krüger, Kulse, Lenke, Lisker, Marschmeyer, Scheit, Schmidt, Schmidt, Schubert, Trusch, Wipf and Wolansky32, Reference Rücker and Heinemann33]). The technology offers SiGe HBTs which a transit frequency f _T of $470\,\mathrm{GHz}$, a maximum oscillation frequency f _max of $650\,\mathrm{GHz}$, and breakdown voltages of $1.5\,\mathrm{V}$ $\mathrm{BV_{CEo}}$ and $3.7\,\mathrm{V}$ $\mathrm{BV_{CBo}}$. The set of passive elements includes salicided and unsalicided poly-silicon resistors, metal-insulator-metal (MIM) capacitors, and MOS-based Varicaps. The metal stack consists of seven aluminum layers including five fine-structured layers and two thick top metal layers with thicknesses of $2\,{\mu m}$ and $3\,{\mu m}$, respectively, for transmission lines, inductors, and transformers.

Due to compatibility issues with software packages used at the time of circuit design, no parasitic extractions could be performed on the designed circuit cores. Parasitics capacitances were estimated based on experience made in other $130\,\mathrm{nm}$ SiGe technologies [Reference Bredendiek, Pohl, Jaeschke, Aufinger and Bilgic11, Reference Thomas, Bredendiek, Jaeschke, Vogelsang and Pohl34]. EM simulations of the designed circuit layouts were performed using Sonnet to optimize the performance of the developed circuit elements.

120 GHz VCO

A VCO is used to generate the signal on this fully integrated FMCW radar MMIC, in contrast to many other publications in the THz range, which use an external signal generation approach [Reference Mangiavillano, Kaineder, Aufinger and Stelzer17, Reference Baumann, Gashi, Meier and Zech20]. When deciding on a center frequency $\left(f_\mathrm{c}\right)$ and subsequent frequency multiplication factor to generate the targeted output frequency, careful consideration has to be taken regarding the circuit architecture, tuning range, and phase noise of the oscillator. While for lower center frequencies, the phase noise, and the relative tuning range are better compared to higher frequencies, doubling the frequency results in an addition of $6\,\mathrm{dB}$ to the phase noise [Reference Siddiq, Hobden, Pennock and Watson35]. Due to the unavailability of parasitic extracted circuit simulations, a center frequency of $120\,\mathrm{GHz}$ was chosen, due to experience based on other $130\,\mathrm{nm}$ SiGe BiCMOS technologies. Furthermore, a center frequency of $120\,\mathrm{GHz}$ ensures a large distance of the targeted fourth harmonic at $480\,\mathrm{GHz}$ to other unwanted harmonics, primarily the third and fifth harmonic, at 360 and $600\,\mathrm{GHz}$ respectively.

The VCO of this MMIC is based on the differential Colpitts oscillator topology. A common base amplifier is used at the oscillator’s output to increase the output power. It is used to drive the subsequent frequency doubler and to decouple the oscillator from influences of the following circuit stages. A voltage-controlled MOSCAP is used as the tunable circuit element of the VCO. The oscillator’s output frequency can be controlled by tuning voltages between −1 and $+5\,\mathrm{V}$. The schematic diagram of the implemented VCO is depicted in Fig. 3.

Figure 3. Schematic diagram of the implemented $120\,\mathrm{GHz}$ VCO. The length of the transmission line L_B can be altered with laser fuses to configure the center frequency of the oscillator.

As circuits in this frequency range are highly susceptible to parasitic influences, like parasitic capacitances, which in this case, influence the oscillator’s output frequency and phase noise, laser fuses were implemented to compensate for these parasitic effects and manufacturing variances. These fuses can be removed after production to lower the center frequency $f_\mathrm{c}$ of the oscillator (119–$108.5\,\mathrm{GHz}$). The measurement results of this fully integrated signal source can be seen in Fig. 4.

Figure 4. Measured output power and phase noise of the integrated $120\,\mathrm{GHz}$ VCO. No fuses were cut for this measurement. The phase noise was measured at an offset frequency $\Delta f$ of $1\,\mathrm{MHz}$.

The VCO, set to the highest center frequency of around $119\,\mathrm{GHz}$ can be tuned from 110.7 to $126.7\,\mathrm{GHz}$, which leads to a tuning range (TR) of $16\,\mathrm{GHz}$ and relative tuning range (rTR) of 13.7%. The output power was determined to be around $7.1\,\mathrm{dBm}$ with a flatness of $1.2\,\mathrm{dB}$ while having a power consumption of only $78\,\mathrm{mW}$. This leads to a dc-to-RF efficiency of up to 6.6%. The measured phase noise is between −72.5 and $-82\,\mathrm{dBc/Hz}$ at an offset frequency $\Delta f$ of $1\,\mathrm{MHz}$. This phase noise measurement was performed using a Rohde & Schwarz FSWP Phase Noise Analyzer at the output of the integrated frequency divider. Due to the frequency translation of the by 16 divider, the measured phase noise was corrected by $24\,\mathrm{dB}$. These measurements were performed on a dedicated breakout MMIC just containing the VCO and frequency divider (published in [Reference Vogelsang, Starke, Wittemeier, Rücker and Pohl36]).

120–240 GHz Gilbert frequency doubler

A bootstrapped Gilbert-cell frequency doubler is used to double the frequency of the differential signal generated by the oscillator. This doubler architecture has differential input and output ports and is suitable for wideband applications [Reference Kueppers, Aufinger and Pohl38]. A previous version of this circuit was published in [Reference Vogelsang, Starke, Wittemeier, Rücker and Pohl36], detailing the measurement results of a breakout MMIC, containing this frequency doubler. A schematic diagram of the implemented frequency doubler is depicted in Fig. 5.

Figure 5. Schematic diagram of the developed $120 - 240{}\mathrm G\mathrm H\mathrm z$ frequency doubler, based on a bootstrapped Gilbert-Cell topology.

This circuit version introduced a power splitter that splits the $240\,\mathrm{GHz}$ signal into the Rx and Tx path between the frequency doubler and the PAs in the respective signal paths. As we used identical power amplifiers in the Tx and Rx paths, we directly split the signal instead of implementing two Wilkinson power dividers for the differential signal.

240–480 GHz push–push frequency doubler

The desired output frequency of $480\,\mathrm{GHz}$ of the radar system is almost equal to the transit frequency f _T of $470\,\mathrm{GHz}$ of the used transistors in the SG13G3 technology. Therefore, the second frequency doubling stage is implemented as a push-push frequency doubler, as these can reach comparatively high output powers even above the respective transit frequencies of the used transistors. Furthermore, push-push doublers achieve high fundamental suppression due to the operating principle of the frequency doubling. A downside typically brought up when using push-push doublers is the conversion from a differential input signal to a single-ended output signal. This is no drawback in this application, as a single-ended patch antenna can be used as Tx antenna. Therefore, no additional balun needs to be used to drive the antenna. A schematic diagram of the developed push–push architecture-based frequency doubler is depicted in Fig. 6.

Figure 6. Schematic diagram of the implemented $240-480{}\mathrm G\mathrm H\mathrm z$ push–push frequency doubler.

Frequency doublers in the lower THz range often use power combining to reach even higher output powers than possible with a single doubler [Reference Güner, Mausolf, Wessel, Kissinger and Schmalz40]. However, in this MMIC, we did not use power combining to keep the space and power consumption requirements low.

Previous research and publications [Reference Wittemeier, Vogelsang, Starke, Rücker and Pohl39] have shown the importance of the interface between the PAs and the push-push doubler circuit. This interface and the inductive load of the doubler stage were optimized in this circuit revision to improve the output power of the doubler by more than $6\,\mathrm{dB}$ in relation to the previous version. This improvement was achieved, influencing neither the transistor sizes, the power consumption, nor the common-base stage of the PAs. The output power of the second frequency doubling stage was characterized on a separate radar MMIC that was just manufactured for circuit measurement and system characterization purposes. It is similar to the MMIC shown in Fig. 1, but GSG probe pads at the doubler’s output and the mixer’s input are placed instead of the patch antennas.

Using this MMIC, an output power of up to $-12.6 \, \mathrm{dBm}$ with a supply voltage of $3.3\,\mathrm{V}$ and up to $-9.4 \, \mathrm{dBm}$ with a supply voltage of $4 \,\mathrm{V}$ was measured for this circuit. The measurement results of the $240$ to $480\,\mathrm{GHz}$ frequency doubler for different fuse configurations of the VCO core are depicted in Fig. 7. The output power of the circuit is measured using an Erickson PM5B power meter with a corresponding Formfactor T-Wave Probe and a WR2.2 to WR10 rectangular waveguide taper. The losses of the probe, taper, and GSG pad are de-embedded from the measured output power using measurement data of these elements.

Figure 7. Output power measurements of the second frequency doubler for different fuse configurations of the VCO. To investigate the maximum output power of the circuit, the supply voltage was increased to $4\,\mathrm{V}$ for the final measurement with three fuses cut.

It can be seen that the performance of the 240–$480\,\mathrm{GHz}$ frequency doubler is mainly limited by the tuning range of the VCO. Below a frequency of $470\,\mathrm{GHz}$, the output power of the doubler is mainly flat, with only a minor difference between the individual measurement curves. The difference between the curves can be explained by the fact that the MMIC has to be removed from the wafer-prober to cut the fuses and re-contacted with the probes for the subsequent measurement. Slight variations in the probes’ positioning and in contact resistance lead to minor differences in the measurement curves.

480 GHz subharmonic mixer

The dynamic range of the radar MMIC is mainly influenced by the transmit power of the Tx path and the receive mixer in the Rx path. Subharmonic mixer architectures are often used for THz applications, as the receive signal frequency is above the transit frequency f _T of the used technology [Reference Deng, Lu, Jia, Yang and Zhu41–Reference Zhou and Luo43]. Therefore, a subharmonic receive mixer architecture was implemented for this radar MMIC. A Gilbert cell with an integrated frequency doubler, utilizing quadrature LO signals, is used in this transceiver (similar to [Reference Kodkani and Larson44]). A schematic diagram of this implementation is given in Fig. 8. The quadrature LO signals are created by two microstrip branchline couplers fed by the PAs described in Section “240 GHz power amplifier”.

Figure 8. Schematic diagram of the implemented subharmonic $480\,\mathrm{GHz}$ receive mixer. The LO input signals $\mathrm{I}$, $\mathrm{\overline{I}}$, $\mathrm{Q}$, and $\mathrm{\overline{Q}}$ are generated by two microstrip branchline couplers.

One potential downside of this circuit architecture is the susceptibility of this circuit to amplitude or phase imbalances of the quadrature LO signals $\mathrm{I}$ and $\mathrm{Q}$ generated by the integrated microstrip branchline couplers. Although these couplers were carefully EM-simulated during the circuit design, the receiver circuit should still be investigated on its susceptibility to amplitude and phase errors. To perform this investigation, the LO signals $\mathrm{I}$ and $\mathrm{Q}$ are generated by microwave ports, and artificial phase and amplitude errors are introduced to this simulation for LO input frequencies between 200 and $250\,\mathrm{GHz}$. When simulating phase errors of up to 30^∘, e.g., a relative phase between $\mathrm{I}$ and $\mathrm{Q}$ of 60^∘ to 120^∘, a maximum degradation of the conversion gain of just 1.39 $\mathrm{dB}$ could be determined. By introducing an amplitude error of up to 3 $\mathrm{dB}$ between $\mathrm{I}$ and $\mathrm{Q}$ signals, a maximum conversion gain degradation of just 1.3 $\mathrm{dB}$ could be determined. These simulation results demonstrate the robustness of the developed receiver circuit against phase and amplitude imbalances. Combined with the carefully EM-simulated couplers generating the quadrature signals $\mathrm{I}$ and $\mathrm{Q}$, this circuit architecture ensures a robust operation over the targeted frequency range.

Using the alternate characterization MMIC, already described in Section “240–480 GHz push-push frequency doubler”, the operation of the receive mixer was successfully verified by feeding the MMIC with an artificial receive signal and generating the LO signals on-chip. Using a Keysight MSOS804A oscilloscope, a peak conversion gain of $-16\, \mathrm{dB}$ was achieved at a frequency of $474\,\mathrm{GHz}$ [Reference Starke, Wittemeier, Vogelsang, Sievert, Erni, Rennings, Rucker and Pohl26].

On-chip 480 GHz antennas

To transmit and receive the radar signals, the push–push frequency doubler and subharmonic mixer are connected to two patch antennas integrated on the MMIC. The antennas are designed for a center frequency $f_\mathrm{c}$ of $480\,\mathrm{GHz}$ and have a length of around $150\,\mu\mathrm{m}$. To improve the matching of the antennas, inset feeding is implemented in both the single-ended transmit antenna Tx and the differential receive antenna Rx.

For characterization purposes, the Tx antenna was manufactured on a breakout MMIC with GSG probe pads and was measured with the setup from [Reference Sievert, Svejda, Erni and Rennings45].

In Fig. 9, the measurement results for the antenna at a frequency of $480\,\mathrm{GHz}$ are shown as $\vec{E}$- and $\vec{H}$-plane cuts. A maximum gain of $3\,\mathrm{dBi}$ was measured at a frequency of $460\,\mathrm{GHz}$. Overall the measurements show a good agreement compared to the full-wave FDTD simulation results.

Figure 9. Realized gain at $480\,\mathrm{GHz}$: (a) $\vec{E}$- and (b) $\vec{H}$-plane of the Tx patch antenna.

It should be noted that, due to the high frequency, reflections from the probe contribute to the measured radiation pattern yielding the undulations on the measured patterns [Reference Boehm, Hitzler, Roos and Waldschmidt46]. Furthermore, a part of the measured radiation pattern is shadowed by the probe. Hence, the measurement results cannot be interpreted here [Reference Titz, Ferrero and Luxey47]. The Rx antenna is not characterized, as it is highly similar to Tx, and would, however, require a balun and more breakout-chip area for separate measurement.

Dielectric lens antenna

To improve the measurement range and focus the radar beam in one direction, a dielectric lens, based on the work in [Reference Thomas, Bredendiek, Jaeschke, Vogelsang and Pohl34, Reference Pohl48, Reference Pohl and Gerding49], was developed to enhance the antenna gain described in Section “On-chip 480 GHz antennas”. In addition to improving the antenna gain, the dielectric lens has the supplementary benefit of shielding the radar MMIC against outside influences and protecting the fragile wire bonds, connecting the MMIC to the FR4 frontend PCB.

The dielectric lens is based on a rotationally symmetrical elliptical lens manufactured from PTFE. This material was chosen for its low dielectric loss tangent $tan~\delta \approx 0.0004$, dielectric constant $\epsilon_r = 2.08$, and good machining properties [Reference Thomas, Bredendiek, Jaeschke, Vogelsang and Pohl34, Reference Pohl48, Reference Pohl and Gerding49]. The shape of the elliptic lens is given by a modification of the standard ellipse equation:

(1)\begin{equation} 1= \left(\frac{x}{a}\right)^2+\left(\frac{y}{R}\right)^2. \end{equation}

When the feeding of the lens is done at the focal point F ₁ of the lens, which is located at a distance f from the center C of the ellipse, and the quasi-optic rays are refracted parallel to the rotation axis in the boresight direction of x [Reference Olver and Saleeb50], the distance f can be calculated depending on the radius of the lens R and the dielectric constant $\epsilon_{\mathrm{r}}$ of the lens material (cf. (2)). The cross-section of this concept can be seen in Fig. 10.

Figure 10. Cross-section of the lens concept.

(2)\begin{equation} f=R\cdot \tan\left(\sin^{-1}\left(\frac{1}{\sqrt{\epsilon_r}}\right)\right)=R\cdot \frac{1}{\sqrt{\epsilon_r-1}}. \end{equation}

The second semi-axis a of the lens can also be calculated depending on the radius R and the dielectric constant $\epsilon_\mathrm{r}$, as the quasi-optic rays have to form a plane phase front at the tip of the lens. This means that the following equation has to be true:

(3)\begin{equation} \frac{\sqrt{\epsilon_r}}{c_0}\cdot (\,f+a) =P\cdot \frac{\sqrt{\epsilon_r}}{c_0} + a\cdot\frac{1}{c_0}.\\[4pt] \end{equation}

By rearranging (3), the length of the second semi-axis a can be calculated:

(4)\begin{equation} a= R\cdot \frac{\sqrt{\epsilon_r}}{\sqrt{\epsilon_r-1}}= R\cdot \frac{1}{\sqrt{1-\frac{1}{\epsilon_r}}}. \end{equation}

Substituting the results from (2) and (4) into (1) and defining the feeding point of the lens at the focal point F ₁, the shape of the dielectric lens can be described in dependence of the radius R and the dielectric constant ϵ_r of the lens:

(5)\begin{equation} 1 = \left(\frac{x-f}{a}\right)^2+\left(\frac{y}{R}\right)^2, \end{equation}

(6)\begin{equation} \qquad\quad\hspace{6.6pt}=\left(\frac{x-\frac{R}{\sqrt{1-1/\epsilon_r}}}{\frac{R}{\sqrt{1-1/\epsilon_r}}}\right)^2+\left(\frac{y}{R}\right)^2. \end{equation}

The radius R of the lens can be chosen depending on the targeted application, antenna gain, and form factor of the radar system. To estimate the directivity D of the dielectric lens, the following estimation was used [Reference Stutzman51]:

(7)\begin{equation} D= \frac{4\cdot\pi \cdot A_E}{\lambda^2}. \end{equation}

In this equation, the losses of the dielectric lens antenna are neglected. Using the approximation of $A_E \approx \pi\cdot R^2$, a maximum theoretical directivity of $45\,\mathrm{dBi}$ can be calculated for a dielectric lens with a radius $R=18\,\mathrm{mm}$ using Eq. (7). A radius of $R=18\,\mathrm{mm}$ was chosen because of the aspect that a small and lightweight THz radar system is going to be implemented with this lens. Hence, this radius is a good tradeoff between the small form factor and the targeted measurement range of the radar system.

To verify this approximation, a simulation model was implemented in CST Microwave Studio. There is a large discrepancy between the feature size of the on-chip antennas, which have a minimum feature size of $420\,\mathrm{nm}$, and the dielectric lens, which has a radius R of $18\,\mathrm{mm}$. Because of this discrepancy, a simulation of the on-chip antennas in combination with the dielectric lens would take vast amounts of time and simulation power. Therefore, a two-stage approach was chosen for this simulation to assess the performance of the patch antennas in conjunction with the lens.

As a first step, the on-chip patch antennas were simulated, and near-field sources of both antennas were created. These near-field sources were included in the simulation environment of the dielectric lens. In this simulation environment, the physical construction of the MMIC in an open QFN package inside a cavity of the lens is modeled, as depicted in Fig. 11. The dielectric lens and QFN package are mounted on an FR4 PCB with a grounded metal plane as the top layer. Including the mounting interface to attach the lens to the PCB, the lens has a height of $43.3\,\mathrm{mm}$.

Figure 11. Cross-section of the presented assembly. The dielectric lens is visualized by a non-functional 3D-printed cut model.

The simulation results of the transmit and receive path in the $\vec{E}$- and $\vec{H}$-plane using this model and the detailed two-step simulation approach can be seen in Fig. 12(a) and 12(b).

Figure 12. Simulation results of the proposed MMIC and dielectric lens combination in the $\vec{E}$ and $\vec{H}$-plane. Squinting beams for the Rx and Tx path can be observed in the $\vec{E}$-plane, but not in the $\vec{H}$-plane. No squinting can be observed for the resulting effective beams in $\vec{E}$ or $\vec{H}$-plane. (a) Directivity: $\vec{E}$-plane. (b) Directivity: $\vec{H}$-plane.

It can be seen that both paths of the radar system, transmit path (Tx) as well as receive path (Rx), have a distinctive peak of the directivity of around $41.7\,\mathrm{dBi}$ with a half-power beam width (HPBW) of 1.5${}^{\circ}$. Because of the bistatic approach, the on-chip antennas cannot be placed in the symmetry plane of the dielectric lens in the $\vec{E}$-plane but are shifted $175\,\mu\mathrm{m}$ to either side of the symmetry plane. This shift leads to two squinting beams with a beam direction of 0.5${}^{\circ}$ in either direction.

As the presented transceiver has a separate transmit and receive path with corresponding integrated antennas, it has to be handled as a bistatic radar sensor. The radar range equation for a bistatic radar system is given by:

(8)\begin{equation} P_{\mathrm{Rx}}= P_{\mathrm{Tx}} \frac{D_{\mathrm{Tx}} D_{\mathrm{Rx}} \lambda^2 \sigma}{(4\pi)^3 R_{\mathrm{Tx}}^2 R_{\mathrm{Rx}}^2}.\\[2pt] \end{equation}

In this equation, the power at the receiver $P_{\mathrm{Rx}}$ is dependent on the power from the transmitter $P_{\mathrm{Tx}}$, the directivities of the receive ($D_{\mathrm{Rx}}$) and transmit ($D_{\mathrm{Tx}}$) antenna, the wavelength λ of the radar signal, the radar cross-section σ of the target, and the distances between the transmitter and receiver to the target, described by the factors $R_{\mathrm{Tx}}$ and $R_{\mathrm{Rx}}$. Due to the small pitch between transmit and receive antenna, the distances $R_{\mathrm{Tx}}$ and $R_{\mathrm{Rx}}$ are practically identical. Therefore the term $R_{\mathrm{Tx}}^2 R_{\mathrm{Rx}}^2$ in Eq. 8 can be replaced by R ⁴. The system can also be handled as a monostatic radar transceiver because of the small distance between the transmitter and receiver and the similar transmit and receive characteristics. The term $D_{\mathrm{Tx}} D_{\mathrm{Rx}}$ can be replaced by $D_{\mathrm{eff}}^2$, where $D_{\mathrm{eff}}$ describes the effective directivity of the radar system. This simplifies Eq. 8 to the following equation for a monostatic radar system:

(9)\begin{equation} P_{\mathrm{Rx}}= P_{\mathrm{Tx}} \frac{D_{\mathrm{eff}}^2 \lambda^2 \sigma}{(4\pi)^3 R^4}.\\[2pt] \end{equation}

This effective directivity represents the bistatic squinting assembly, with a monostatic model calculated by combining the directivities in transmit and receive operation. It can be determined by calculating the geometric mean of the Tx and Rx directivity for every angle θ and φ:

(10)\begin{equation} D_{\mathrm{eff}}(\theta,\varphi)= \sqrt{D_{\mathrm{Tx}}(\theta,\varphi)\cdot D_{\mathrm{Rx}}(\theta,\varphi)}. \end{equation}

The effective directivity, calculated by the equation above (10), is depicted in black in Fig. 12(a) and 12(b). The effective directivity has its peak in the boresight direction and is approximately $2.4\,\mathrm{dB}$ lower than the respective Tx and Rx beams in the $\vec{E}$-plane. Due to the small pitch of the antennas of only $350\,\mu\mathrm{m}$, the geometric mean of both individual beams leads to a distinctive peak of $39.33\,\mathrm{dBi}$ in the $\vec{E}$-plane. Because of the combination of the two squinting beams, the sidelobe level in the $\vec{E}$-plane is considerably higher than the respective individual Tx and Rx beams, with a value of $7.64\,\mathrm{dB}$. The HPBW of the effective directivity in the $\vec{E}$-plane is 0.95^∘. As the on-chip antennas lie on the symmetry plane for the directivity in the $\vec{H}$-plane, no squinting of the Rx and Tx beams can be observed in Fig. 12(b). The effective directivity in the $\vec{H}$-plane reaches a value of $39.3\,\mathrm{dBi}$ in boresight direction with an HPBW of 0.95^∘ and a sidelobe level of $11.91\,\mathrm{dB}$.

The simulation results show that this dielectric lens enables a compact and low-cost 0.48 THz FMCW radar system with a small beam width and high suppression of unwanted targets for high-accuracy measurement scenarios.

Comparison to state-of-the-art electronic THz transceivers

In Table 1, the proposed $0.48\,\mathrm{THz}$ transceiver is compared to the state of the art in electronic THz transceivers. The comparison of the size and power consumption P_dc has to be split between systems with external signal generation, typically using a laboratory signal generator, and the transceivers that generate the signal internally with integrated VCOs. As in the realization described in this manuscript, most comparable THz transceivers use lenses to improve the radiation characteristics of the antennas integrated on their respective transceiver MMICs. These lenses are manufactured from multiple different materials, like polymethylpentene (TPX), polypropylene (PP), silicon (Si), or in this case, made from PTFE.

Table 1. Comparison of state-of-the-art integrated electronic THz transceivers

* Size of all MMICs that form the transceiver.

** EIRP.