Chip-to-package-to-PCB interconnect

Three different interconnect structures are demonstrated in this paper, namely, a chip-to-package, a package-to-PCB and a chip-to-package-to-PCB interconnect. All interconnects are demonstrated in a daisy chain/back-to-back configuration to enable probe-based S-parameter measurement.

A chip-to-package interconnect realized by means of eWLB microvias is shown in Fig. 2(a). The design consists of ground plane taper connecting the RF pads on the chip, with a pitch of 125 µm, to the 50Ω CPW line in the RDL layer of an eWLB package. The on-chip through-line is fabricated in 22-nm FDSOI CMOS technology.

Figure 2. Interconnect design (shown without PCB substrate): (a) chip-to-package; (b) package-to-PCB; and (c) complete chip-to-package-to-PCB.

The package-to-PCB interconnect, realized by means of a quasi-coaxial signal transition (see Fig. 2(b)), is designed as follows. The first step in the design of the quasi-coaxial signal transition is to calculate the theoretical characteristic impedance of the quasi-coaxial signal transition, with the following equation from [Reference Pozar22], for the impedance of a coaxial transmission line:

(1)\begin{equation} Z_{\text{coaxial}} = \frac{60}{\sqrt{\epsilon_r}}\text{ln}\left(\frac{r_{\text{outer}}}{r_{\text{inner}}}\right). \end{equation}

As the BGA-based quasi-coaxial signal transition is air-filled, $\epsilon_r=1$. The solder balls of the packages demonstrated in this paper in eWLB technology, have a standard pitch of 500 µm and diameter of 375 µm – see [Reference Hagelauer, Wojnowski, Pressel, Weigel and Kissinger6, Reference Wojnowski, Lachner, Böck, Wagner, Starzer, Sommer, Pressel and Weigel23]. This leads to an initial calculation of $Z_{\text{coaxial}}=31\,\Omega$ for the quasi-coaxial signal transition. The quasi-coaxial transition supports the TEM mode. The cut-off frequency of the $\text{TE}_{11}$ mode of a standard coaxial transmission line can be estimated with the following equation,

(2)\begin{equation} f_{\text{TE}_{11}} = \frac{c}{\pi\sqrt{\epsilon_r}(r_{\text{outer}}+r_{\text{inner}})}. \end{equation}

The cut-off frequency, for the initial design values mentioned above, is $f_{\text{TE}_{11}}=139$ GHz, if one assumes r _outer to be defined as the pitch of the solder balls. This is more than sufficient for the proposed PMCW radar SiP application.

The position of the solder balls, the size of the ground ring on the package and on the PCB, as well as the width of the finite ground plane in the package, is subsequently optimized in CST Studio Suite software – taking into consideration, the design rules of the eWLB manufacturing technology. The simulation model for the optimization process can be seen in Fig. 3(a) – two waveguide ports are placed on either side of the quasi-coaxial signal transition. The insertion and return loss for the optimized signal transition model is given in Fig. 3(b). The characteristic impedance of the optimized quasi-coaxial signal transition is calculated with [Reference Eisenstadt and Eo24]:

(3)\begin{equation} Z_c = Z_0\sqrt{\frac{(1+S_{11})^2-S^2_{21}}{(1-S_{11})^2-S^2_{21}}}. \end{equation}

Figure 3. Quasi-coaxial signal transition: (a) simulation model for optimization and (b) simulation results.

Using Eq. (3), the characteristic impedance is calculated as 40.3 Ω, at a center frequency of 55 GHz. Thereafter, the quasi-coaxial signal transition is connected to 50 Ω CPW lines on the package and PCB.

Two models for the quasi-coaxial signal transition are presented here – Design A (Fig. 4(a)) and Design B (Fig. 4(b)). Design A has been optimized to ensure minimal return and insertion losses over an expansive bandwidth. Contrarily, Design A is characterized by an extended ground plane and reduced inner ground ring diameter compared to Design B, with $d_\text{ring, eWLB} = 0.576$ mm, $ d_\text{ring, PCB} = 0.64$ mm. Design B boasts a more compact footprint, but it incurs a marginally higher insertion loss in comparison with Design A. Design B has a more compact footprint, with narrower ground planes, but it incurs a marginally higher insertion loss in comparison with Design A. The inner diameter of the ground ring on the package is also larger for Design B – $d_\text{ring, eWLB} = d_\text{ring, PCB} = 0.72$ mm. Furthermore, Design B seamlessly integrates with the chip-to-package interconnect presented earlier. Nonetheless, both Designs A and B of the quasi-coaxial signal transition remain viable options; using Design A would merely necessitate adjusting the chip-to-package interconnect to accommodate the broader ground plane. The return and insertion loss of the back-to-back quasi-coaxial-to-CPW signal transition, with a CPW line 1.65 mm long connecting the two quasi-coaxial transitions, are shown in Fig. 4(c), for both designs. A back-to-back model of Design A of the quasi-coaxial signal transition is manufactured, to illustrate the wideband characteristics of the eWLB-based quasi-coaxial signal transition for the first time.

Figure 4. Two models of the quasi-coaxial signal transition: (a) Design A; (b) Design B; and (c) comparison of results.

Lastly, the quasi-coaxial signal transition given in Fig. 4(b) (Design B) is used in the design of the full back-to-back chip-to-package-to-PCB interconnect – see Fig. 2(c) – due to ease of integration and the smaller area requirement. All the interconnects presented in this section use RO4003C, with a thickness of 508 µm as PCB substrate.

eSRR antenna

The design of the eSRR antenna is based on electrically resonant terahertz metamaterial unit cells originally proposed in [Reference Padilla, Aronsson, Highstrete, Lee, Taylor and Averitt25, Reference Chen, O’Hara, Taylor, Averitt, Highstrete, Lee and Padilla26]. Unlike classic SRRs, whose electric and magnetic responses are strongly coupled (resulting in a complex magnetoelectric response), eSRRs have a pure electric response [Reference Padilla, Aronsson, Highstrete, Lee, Taylor and Averitt25]. The symmetrical structure of an eSRR eliminates the magnetoelectric response by counter-circulating currents in the unit cell. Figure 5 shows the design and dimensions of the novel, uniaxial, differential eSRR antenna, that is demonstrated in this paper for the first time. The width of the strip closest to the feed was increased to improve the matching and return loss. The antenna is square, with $l_1 = 0.27\lambda_g$ (λ_g is the guided wavelength) and when including the surrounding finite ground conductor, $l_2 = 0.48\lambda_g$. The antenna is realized in an eWLB package of 4 × 5 mm².

The antenna has a 100 Ω coplanar strip line (CPS) for its feed. A probe-based antenna measurement setup is used [Reference Beer and Zwick27] to characterize D-band antennas from 110 to 170 GHz. For D-band measurements, single-ended probes are used, therefore, a balanced-to-unbalanced (i.e. balun) transition is required when measuring differential antennas. A Chebyshev quarter-wave stepped balun transformer is used for the 50 Ω CPW to 100 Ω CPS transition – previously characterized in [Reference Bhutani, Bekker, Li, de Oliveira and Zwick12]. This balun necessitates bond wires to bridge the finite ground planes. The bond wires are added manually during the assembly process. Two bond wires are added on both sides of the radial slot. The balun’s intended application is solely for the antenna characterization, and considering that MMICs frequently adopt differential outputs, it is not intended for integration into future products. A microscope photo of the differential eSRR antenna prototype, with the aforementioned Chebyshev balun, in the eWLB package, is shown in Fig. 5.

Figure 5. eSRR antenna: (a) simulation model with dimensions and (b) microscope photo of a prototype.

As can be seen from Fig. 1(a), the antenna’s radiation is reflected by the reflector realized on the PCB and therefore radiates through the mold, in the direction opposite of the feedline and probe. In this paper, a simple change is introduced in the conventional eWLB-package-and-PCB assembly, which enhances the gain of an eWLB AiP significantly. Due to the height of the solderballs after soldering and assembly, the usual distance between the antenna and reflector, is approximately 0.1λ, at 140 GHz. By simply increasing the distance between the eWLB AiP and a PCB-based reflector, to 0.25λ, constructive interference of the electric fields should result in a higher antenna gain. Therefore, 290 µm is additionally required between the antenna and the reflector – this is used as the initial value for the depth of the horn-shaped reflector. This idea leads to the proposed modified package concept illustrated in Fig. 1(b), where a horn-shaped reflector is manufactured in the PCB, instead of a planar reflector as was custom in previous publications [Reference Bhutani, Bekker, de Oliveira, Pauli and Zwick11]–[Reference Bekker, Bhutani, de Oliveira, Antes and Zwick14].

Of course, a smooth horn is difficult to realize in alumina substrate. The horn ramp is approximated with steps of 20 µm – see Fig. 6(b). A VBA macro is used to model the layers in CST. It was determined in simulation that as long as the steps are less than 25 µm in height, the AiP performance is similar to that of the simulation model using a smooth horn (Fig. 6(a)). It is further determined, through optimization in CST Studio Suite software, that a slope of 15^∘, and a horn aperture of 2.5 × 2.5 mm² results in an optimum gain value, and a horn height of 260 µm leads to the highest average gain from 130 to 150 GHz. The total substrate thickness of the alumina in which the horn-shaped reflector is realized, is 508 µm – a standard sheet thickness.

Figure 6. Simulation models of horn-shaped reflector of eSRR antenna: (a) simplified model of smooth horn and (b) horn shape approximated by metallized steps.

In Fig. 7, the return loss and the gain of the eSRR antenna, with three different reflectors, are presented – two planar reflectors and the horn-shaped reflector described above. The results for two different planar reflectors are presented – for an antenna with a Rogers 4003C substrate and an alumina substrate. In both cases, the PCB substrate is 508 µm thick with a 2.25 × 2.25 mm² reflector on the PCB. The RO4003C simulation results are included here, to ease comparison with prior works [Reference Bhutani, Bekker, de Oliveira, Pauli and Zwick11]–[Reference Bekker, Bhutani, de Oliveira, Antes and Zwick14] that used a similar substrate. The impedance bandwidth of the three different scenarios are similar – the reflection coefficient is below −10 dB from 127 to 166 GHz (a relative bandwdith of 26.9%). The gain, however, improves quite significantly, with the antenna with the horn-shaped reflector exhibiting a peak gain of 10.2 dBi – an improvement of 2.3 dB from the case of the planar reflector. A significant improvement is especially noticeable at the higher frequencies – an improvement of up to 5.3 dB can be seen around 149 GHz.

Figure 7. Simulation results of eSRR antenna with different reflectors: (a) reflection coefficient and (b) antenna gain.

Laser-structuring

The laser used in this work is the ProtoLaser R4 by LPKF – it is a green picosecond laser for cold ablation with a spot size of 20 µm. It can structure a wide range of materials including widely used PCB materials such as the gold-coated alumina or copper-plated RO4003C used in this work. For the interconnects, one side of the RO4003C substrate is structured using this laser – see Figs. 8(b), 9(b) and 10(b) for microscope photos of the PCB prototypes. As for the PCB-based reflector, a more involved process is required. A customized process is developed to manufacture the horn-shaped cavity for the antenna reflector, as the machine does not come with such a ready-to-use functionality. As a first step, a simple cavity in alumina is manufactured, and its depth measured. Knowing the depth and the number of hatching repetitions necessary to make the simple cavity allows one to determine the ablation height per repetition. In the next step, the number of repetitions per layer are chosen, so that it would cut 25 µm deep per layer, and thereafter a set of layers with decreasing cavity dimensions, is created. Controlling the difference in size between the layers means controlling the horn slope. A microscope photo of the horn-shaped cavity in the alumina can be seen in Fig. 11(a).

Figure 11. Manufactured prototype of horn-shaped reflector of eSRR antenna: (a) prior to metallization; (b) after metallization with AJ-printing; and (c) step with missing metallization.

Aerosol-jet printing

Aerosol-jet (AJ) printing is a non-contact printing process, that can create feature sizes down to 10 µm and use a wide range of materials – including silver. The working principle is described in [Reference Secor28]. This work required plating the walls and bottom of the previously manufactured horn-shaped reflector. A 100 µm nozzle is the best suited for these constraints. All printing parameters are given in Table 1. The AJ5X printer by Optomec is used here, in a cleanroom environment, and 3-min oxygen plasma pretreatment was applied to the substrates. Thereafter, they were sintered for 5 min on a preheated hotplate at 250 ^∘C. A microscopic image of the metallized horn is shown in Fig. 11(b). In order to obtain a continuous metal layer, an additional deposition step was added on the slopes. As the slope of the cavity is quite steep, some steps might not be metallized – this can be seen in the photo of Fig. 11(c).

Table 1. Aerosol jet printing parameters

Wire bonding and assembly

As mentioned above, two bond wires are added on both sides of the radial slot. An opening was left in the upper dielectric layer of the eWLB package, in the region of the balun, to expose the copper RDL layer. The dielectric opening is only 220 µm × 160 µm. The bond wires are made from gold wire with a diameter of 17.5 µm. As such it is quite challenging to fit all four, such short, bond wires in the limited dielectric opening, without accidentally shorting the signal line. A tungsten wire with a diameter of 50 µm was held in place on the signal line to prevent causing a short circuit with the signal line and to ensure that the final height of the bond wires were approximately 50 µm. The F&S Bondtec Series 56i wire bonder was used. The eWLB packages are manually soldered to the laser-structured PCBs, using the Finetech Fineplacer Lambda. Microscope photos of the assembled packages can be seen in Figs. 8(d, e), 9(c, d), 10(c, d), and 12.

Figure 12. Microscope photo of prototype of eSRR antenna with horn-shaped reflector: (a) top view and (b) side view.