*2.4. Spatial and Angular Misalignment between Tx and Rx Coils*

*Electronics* **2020**, *9*, 1999 systems, the multi-resonator coil arrangemen<sup>t</sup> around the cage, simply driven by a single LC-tank located at the bottom of the cage, can dynamically focus the magnetic field at the position of Rx coil. However, the parasitic resistance in multi-resonator coils still dissipates power all the time regardless of the Rx coil position, resulting in the additional power loss compared to the switchable modular Tx coil design. *2.4. Spatial and Angular Misalignment between Tx and Rx Coils* Spatial and angular misalignments and distance variation between Tx and Rx coils inside the wirelessly-powered cage happen quite frequently in practice as freely behaving animal subjects walk, sniff around, rear, and climb the walls of the cage. This will result in a significant reduction in the PTE and PDL, which might cause malfunctions in the mobile device which does not equip energy storage. The homogeneity of wireless coverage achieved by the Tx coil array alleviates the spatial misalignment as shown in Section 2.1.2, and the CLPC in Section 2.2 [11,13,16] compensates the reduced power in the Rx against some angular misalignments or distance variations. However, the Rx coil rarely receives the wireless power from the Tx coil with maximum angular misalignment of 90°. Therefore, the designer should consider the worst-case condition in the wirelessly-powered cage. 

Spatial and angular misalignments and distance variation between Tx and Rx coils inside the wirelessly-powered cage happen quite frequently in practice as freely behaving animal subjects walk, sniff around, rear, and climb the walls of the cage. This will result in a significant reduction in the PTE and PDL, which might cause malfunctions in the mobile device which does not equip energy storage. The homogeneity of wireless coverage achieved by the Tx coil array alleviates the spatial misalignment as shown in Section 2.1.2, and the CLPC in Section 2.2 [11,13,16] compensates the reduced power in the Rx against some angular misalignments or distance variations. However, the Rx coil rarely receives the wireless power from the Tx coil with maximum angular misalignment of 90◦. Therefore, the designer should consider the worst-case condition in the wirelessly-powered cage. The most common technique to address the angular misalignment with omnidirectional powering is to implement 3D Rx coils in x-, y-, and *z*-axis, as shown in Figure 10a [20]. The 3D Rx coil is composed of three individual Rx coils followed by each rectifier as shown in Figure 10b. For the nominal condition which angular misalignment is 0◦, the Rxz coil mainly receives the power carrier from the Tx coils while Rxx and Rxy coils rarely receive the power. When the 3D Rx coil has large angular misalignments from the Tx coil, the received power in the Rxx or Rxy coil is increased depending on the misalignment axis to compensate the reduced power in the Rxz coil. The 3D Rx coil can also be implemented by using the multiple resonator coils, *L*3, instead of multiple load coils, *L*4, as introduced in Figure 11 [14]. As shown in Figure 11b, the multiple resonators are strongly coupled with *L*4, while the multiple resonators can receive the power against angular misalignment inside the cage. This technique only utilizes one rectifier resulting in the reduced circuit complexity compared to Figure 11b. Since these 3D Rx coils receive the inductive power from each direction, it provides better homogeneous PTE and PDL against the angular misalignments of the mobile device. However, the 3D Rx coil design in the mobile unit increases the volume compared to the conventional single planar Rx coil, resulting in the limited applications for tiny implants inside the animal body. The most common technique to address the angular misalignment with omnidirectional powering is to implement 3D Rx coils in x-, y-, and *z*-axis, as shown in Figure 10a [20]. The 3D Rx coil is composed of three individual Rx coils followed by each rectifier as shown in Figure 10b. For the nominal condition which angular misalignment is 0°, the Rxz coil mainly receives the power carrier from the Tx coils while Rxx and Rxy coils rarely receive the power. When the 3D Rx coil has large angular misalignments from the Tx coil, the received power in the Rxx or Rxy coil is increased depending on the misalignment axis to compensate the reduced power in the Rxz coil. The 3D Rx coil can also be implemented by using the multiple resonator coils, *L*3, instead of multiple load coils, *L*4, as introduced in Figure 11 [14]. As shown in Figure 11b, the multiple resonators are strongly coupled with *L*4, while the multiple resonators can receive the power against angular misalignment inside the cage. This technique only utilizes one rectifier resulting in the reduced circuit complexity compared to Figure 11b. Since these 3D Rx coils receive the inductive power from each direction, it provides better homogeneous PTE and PDL against the angular misalignments of the mobile device. However, the 3D Rx coil design in the mobile unit increases the volume compared to the conventional single planar Rx coil, resulting in the limited applications for tiny implants inside the animal body. Instead of the 3D Rx coil, the new Tx coil configurations are studied to provide the homogeneous magnetic field along with x-, y-, and *z*-axis [21,22]. The proposed architecture in Figure 12a [21] includes three layers of hexagonal planar spiral coil (hex-PSCs) array for homogeneous distribution of the PTE against angular misalignments. The individual Tx coil array generates power carriers with three phases (0°, 120°, 240°) as shown in Figure 12b, and provides both vertical and lateral magnetic fluxes at the same time over the entire powered 3D volume inside the cage. When the Rx coil is aligned with the Tx coil, the Rx coil can receive the power from the vertical magnetic flux. When the Rx coil has the angular misalignment against the Tx coil by 90°, the lateral magnetic flux between the Tx coils mainly provides the power to the Rx, resulting in ~4% PTE improvement compared to the conventional Tx coil array as shown in Figure 12b. 

**Figure 10.** (**a**) The design of the 3D Rx coil structure and (**b**) circuit diagrams in [20] to compensate for the angular misalignment of Rx coil.

*Electronics* **2020**, *9*, 1999 **Figure 10.** (**a**) The design of the 3D Rx coil structure and (**b**) circuit diagrams in [20] to compensate for the angular misalignment of Rx coil. 

90° angular misalignment from the Tx coils. Although the Rx coil in this system should be designed in the crossed dipole structure with the ferrite material resulting in the limited applications for tiny biomedical implants, the rotating magnetic field technique can be potentially applicable for external portable biomedical devices attached to the animal body. (**a**) (**b**) **Figure 12.** (**a**) The design of the 3D Tx coil using multiple resonators in the wirelessly-powered cage, and (**b**) the three-phase magnetic field excitation scheme [21]. **Figure 12.** (**a**) The design of the 3D Tx coil using multiple resonators in the wirelessly-powered cage, and (**b**) the three-phase magnetic field excitation scheme [21].

In [22], the omnidirectional powering is achieved by two dipole coils using DQ rotating magnetic field. This technique utilizes the phase differences in two Tx coils, Tx-D, and Tx-Q, and then, generates the rotating magnetic field in the 3D volume as shown in Figure 13. The AC currents in the Tx-D and Tx-Q have same magnitude with 90° phase difference from each other. These two currents generate the transient magnetic field along with x-, y-, and z-directions by rotating the angular frequency from 0 to 2Δ as partly shown in Figure 13b–d. Then, the crossed dipole Rx coil can still receive the wireless power from a portion of rotating magnetic fields even though it has the maximum 90° angular misalignment from the Tx coils. Although the Rx coil in this system should be designed in the crossed dipole structure with the ferrite material resulting in the limited applications for tiny biomedical implants, the rotating magnetic field technique can be potentially applicable for external portable biomedical devices attached to the animal body. In [22], the omnidirectional powering is achieved by two dipole coils using DQ rotating magnetic field. This technique utilizes the phase differences in two Tx coils, Tx-D, and Tx-Q, and then, generates the rotating magnetic field in the 3D volume as shown in Figure 13. The AC currents in the Tx-D and Tx-Q have same magnitude with 90◦ phase difference from each other. These two currents generate the transient magnetic field along with x-, y-, and z-directions by rotating the angular frequency from 0 to 2π as partly shown in Figure 13b–d. Then, the crossed dipole Rx coil can still receive the wireless power from a portion of rotating magnetic fields even though it has the maximum 90◦ angular misalignment from the Tx coils. Although the Rx coil in this system should be designed in the crossed dipole structure with the ferrite material resulting in the limited applications for tiny biomedical implants, the rotating magnetic field technique can be potentially applicable for external portable biomedical devices attached to the animal body. *Electronics* **2020**, *9*, x FOR PEER REVIEW 13 of 28 

**Figure 13.** (**a**) The design of two crossed-dipole coils for Tx-D (Tx1, *x*-axis) and Tx-Q (Tx2, *y*-axis) coils for generating omnidirectional magnetic fields, and the simulated rotating magnetic flux at relative angular frequency of (**b**) 0 (**c**) Δ/4, and (**d**) Δ/2 [22]. **Figure 13.** (**a**) The design of two crossed-dipole coils for Tx-D (Tx1, *x*-axis) and Tx-Q (Tx2, *y*-axis) coils for generating omnidirectional magnetic fields, and the simulated rotating magnetic flux at relativeangular frequency of (**b**)0(**c**) π/4, and (**d**) π/2 [22].

#### *2.5. Near-Field Data Telemetry 2.5. Near-Field Data Telemetry*

Since the IMD in the wirelessly-powered cage typically monitors different types of biomedical signals recorded from the electrodes and performs stimulation to tissue for the treatment, the data transmission between the mobile device and the wirelessly-powered cage is required to collect the data and to control the device. In terms of the average power dissipation in the recent IMDs, composed of amplifiers, signal conditioning, digitization, processing, and radio frequency (RF) transmission blocks for neural recording application, the traditional far-field data communication blocks dedicate a relatively large portion of the IMD power budget compared to the other functional blocks [7]. Therefore, the near-field communication can be regarded as a more suitable method in terms of power saving in IMDs, considering that the animal subject moves within the wirelesslypowered cage, and the Tx/Rx coils are already implemented for the wireless powering. While there have been many data telemetry techniques are introduced, it is important for the designers to select suitable data telemetry methods, considering the practical limitations of IMD design related to key aspects, such as power budget, silicon area, IMD dimensions, temperature elevation, data bandwidth, sensitivity, reliability (Bit-Error Rate, BER), and robustness against various perturbations [7]. Since the IMD in the wirelessly-powered cage typically monitors di fferent types of biomedical signals recorded from the electrodes and performs stimulation to tissue for the treatment, the data transmission between the mobile device and the wirelessly-powered cage is required to collect the data and to control the device. In terms of the average power dissipation in the recent IMDs, composed of amplifiers, signal conditioning, digitization, processing, and radio frequency (RF) transmission blocks for neural recording application, the traditional far-field data communication blocks dedicate a relatively large portion of the IMD power budget compared to the other functional blocks [7]. Therefore, the near-field communication can be regarded as a more suitable method in terms of power saving in IMDs, considering that the animal subject moves within the wirelessly-powered cage, and the Tx/Rx coils are already implemented for the wireless powering. While there have been many data telemetrytechniques are introduced, it is important for the designers to select suitable data telemetry methods, considering the practical limitations of IMD design related to key aspects, such as power budget, silicon area, IMD dimensions, temperature elevation, data bandwidth, sensitivity, reliability (Bit-Error Rate, BER), and robustness against various perturbations [7].

#### *2.6. Specific Absorption Ratio (SAR) and Safety Issues 2.6. Specific Absorption Ratio (SAR) and Safety Issues*

The transmitted power from the Tx coil should be less than allowable specific absorption rate (SAR) limit, determined by the induced electric field intensity, E, in tissue when exposed to a RF EM field. There are mainly two official international safety standard establishment organizations which have deeply impacted each country for their safety standards. The International Commission on Non-Ionizing Radiation Protection (ICNIRP) has the series exposure guideline for each E-field and H-field. The recent ICNIRP (2010) used the induced E-Field instead of induced current density metric. Meanwhile, the guideline also provided the exposure limits in central nervous system (CNS) tissues of the head and other tissues of the body. Institute of Electrical and Electronics Engineers (IEEE) also provided [23] for exposure standard. Compared with ICNIRP guideline, IEEE standard is widely used in US, Canada, Japan, Korea, etc. It also has basic restriction and reference restriction. When setting protective limits for localized tissue heating due to the difficulty of SAR measurement, the point SAR is mass averaged, in recognition of the thermal diffusion properties of tissue. The averaging mass in ICNIRP is any 10 g of contiguous tissue. IEEE standard specifies a smaller 1 g averaging mass in the shape of a cube. The IEEE limits differ from the ICNIRP guidelines in both the maximum level specified which are 100 W/mm2 for IEEE and 50 W/m2 for ICNIRP, and the frequency at which these peak values reach are 2000 MHz for ICNIRP and 3000 MHz for IEEE [24]. The transmitted power from the Tx coil should be less than allowable specific absorption rate(SAR) limit, determined by the induced electric field intensity, E, in tissue when exposed to a RFEM field. There are mainly two o fficial international safety standard establishment organizations which have deeply impacted each country for their safety standards. The International Commission on Non-Ionizing Radiation Protection (ICNIRP) has the series exposure guideline for each E-field and H-field. The recent ICNIRP (2010) used the induced E-Field instead of induced current density metric. Meanwhile, the guideline also provided the exposure limits in central nervous system (CNS) tissues of the head and other tissues of the body. Institute of Electrical and Electronics Engineers (IEEE) also provided [23] for exposure standard. Compared with ICNIRP guideline, IEEE standard is widely used in US, Canada, Japan, Korea, etc. It also has basic restriction and reference restriction. When setting protective limits for localized tissue heating due to the di fficulty of SAR measurement, the point SAR is mass averaged, in recognition of the thermal di ffusion properties of tissue. The averaging mass in ICNIRP is any 10 g of contiguous tissue. IEEE standard specifies a smaller 1 g averaging mass in the shape of a cube. The IEEE limits di ffer from the ICNIRP guidelines in both the maximum level specified which are 100 <sup>W</sup>/mm<sup>2</sup> for IEEE and 50 <sup>W</sup>/m<sup>2</sup> for ICNIRP, and the frequency at which these peak values reach are 2000 MHz for ICNIRP and 3000 MHz for IEEE [24].

SAR can be calculated by *Η*|E|2/*Ε*, where *Η* and *Ε* are tissue conductivity and density, respectively. Since the SAR limit allows the less amount of RF exposure for the higher carrier frequency, the designer also needs to select a suitable power carrier frequency for the wirelesslypowered cage system based on the expected maximum power used in the Tx and SAR limit for safety, prior to the PTE or PDL optimization. RF exposure can be evaluated by the simulation using a 117

SAR can be calculated by <sup>σ</sup>|E|<sup>2</sup>/ρ, where σ and ρ are tissue conductivity and density, respectively. Since the SAR limit allows the less amount of RF exposure for the higher carrier frequency, the designer also needs to select a suitable power carrier frequency for the wirelessly-powered cage system based on the expected maximum power used in the Tx and SAR limit for safety, prior to the PTE or PDL optimization. RF exposure can be evaluated by the simulation using a "phantom", which emulates the electrical characteristics of the human head, body, or tissue. In [25], the EM simulator, namely HFSS, is utilized to estimate the peak of average SAR values of tissue layers when a mm-size Rx coil implanted in the tissue receives 1.3 mW power. Under different settings of tissue layers, the SAR values with the WPT configuration of a two-coil link, a three-coil link with loop coils, and a three-coil link with segmented coils are compared, as shown in Figure 14a. Figure 14b shows the SAR simulation results with Poynting vectors (the real component of the power density) generated by the EnerCage-HC2 when the Tx power is 1 W for the rat model. In this simulation setup, the rat model is made entirely out of brain tissue with σ = 105 S/m and ρ = 1040 kg/m3, which generates the worst case for SAR simulation [14]. "phantom", which emulates the electrical characteristics of the human head, body, or tissue. In [25], the EM simulator, namely HFSS, is utilized to estimate the peak of average SAR values of tissue layers when a mm-size Rx coil implanted in the tissue receives 1.3 mW power. Under different settings of tissue layers, the SAR values with the WPT configuration of a two-coil link, a three-coil link with loop coils, and a three-coil link with segmented coils are compared, as shown in Figure 14a. Figure 14b shows the SAR simulation results with Poynting vectors (the real component of the power density) generated by the EnerCage-HC2 when the Tx power is 1 W for the rat model. In this simulation setup, the rat model is made entirely out of brain tissue with *Η* = 105 S/m and *Ε* = 1040 kg/m3, which generates the worst case for SAR simulation [14]. To ensure the safety of EM exposure, SAR can be simulated by various EM simulators, such as HFSS, in the design stage as shown in Figure 14. Additionally, other measures include monitoring the tissue heating using temperature sensor in the IMD [26,27]. Based on the tissue heating information sent from the IMD, the wirelessly-powered cage can limit the amount of transmitted power to conform to the SAR limitation and prevent tissue damage from the abnormal heat generation of the IMD. 

**Figure 14.** Examples of EM simulation of SAR limits for (**a**) lamb's head layers [25] and (**b**) a rat model made entirely out of brain tissue [14]. **Figure 14.** Examples of EM simulation of SAR limits for (**a**) lamb's head layers [25] and (**b**) a rat model made entirely out of brain tissue [14].

**3. Designs of Wirelessly-Powered Cage Systems**  In this section, we will introduce different designs of wirelessly-powered cage systems, which can be classified into four categories. Based on the design considerations discussed in Section 2, we will discuss the main features of each wirelessly-powered cage design. To ensure the safety of EM exposure, SAR can be simulated by various EM simulators, such as HFSS, in the design stage as shown in Figure 14. Additionally, other measures include monitoring the tissue heating using temperature sensor in the IMD [26,27]. Based on the tissue heating information sent from the IMD, the wirelessly-powered cage can limit the amount of transmitted power to conform to the SAR limitation and prevent tissue damage from the abnormal heat generation of the IMD.

*3.1. Wirelessly-Powered Cage Systems with Single Tx Coil Configuration* **3. Designs of Wirelessly-Powered Cage Systems**

The single Tx coil configuration can simplify the design of the driver control in the wirelesslypowered cage systems, significantly improving the system robustness. However, the following examples of the wirelessly-powered cage systems with such configuration also suffer from other limitations, which we will discuss in detail [18,28–30]. In this section, we will introduce different designs of wirelessly-powered cage systems, which can be classified into four categories. Based on the design considerations discussed in Section 2, we will discuss the main features of each wirelessly-powered cage design.

Figure 15a,b show two wirelessly-powered cage designs, each of which a large Tx coil wraps around the cage to enhance the magnetic field within the volume covered by the Tx coil [28,29]. In Figure 15a, the Tx coil comprises two series-connected coaxial rectangular windings, generating an effective operating zone of 40 × 24 × 4 (height) cm [28]. The center of such an operation zone is 7 cm height from the bottom of the cage to cover the vertical movement of the mobile device while the animal is walking and standing. A Δ-capacitor matching circuit, which matches the Rx coil to the *3.1. Wirelessly-Powered Cage Systems with Single Tx Coil Configuration* The single Tx coil configuration can simplify the design of the driver control in the wirelessly-powered cage systems, significantly improving the system robustness. However, the following examples of the wirelessly-powered cage systems with such configuration also suffer from other limitations, which we will discuss in detail [18,28–30].

load, is also designed to ensure the wireless power delivery maintaining at the maximum PDL condition. In Figure 15b, the Tx coil completely encompasses the area in which the animals can roam freely, resulting in an effective space of 40 × 40 × 20 (height) cm3 [29]. These two designs can improve the WPT resilience to lateral and vertical misalignments between the Tx and Rx coils. However, the angular misalignments still can negatively impact the PTE of the inductive link. Moreover, due to huge size difference, the pair of Tx and Rx coils is away from their optimal size matching, resulting in the low PTE of these two designs. For a larger experimental arena, the size of the Tx coil will be Figure 15a,b show two wirelessly-powered cage designs, each of which a large Tx coil wraps around the cage to enhance the magnetic field within the volume covered by the Tx coil [28,29]. In Figure 15a, the Tx coil comprises two series-connected coaxial rectangular windings, generating an effective operating zone of 40 × 24 × 4 (height) cm [28]. The center of such an operation zone is 7 cm height from the bottom of the cage to cover the vertical movement of the mobile device while the animal is walking and standing. A π-capacitor matching circuit, which matches the Rx coil to the load, is also designed to ensure the wireless power delivery maintaining at the maximum PDL condition. area of the circular mouse cage. Such a configuration is also not conductive for the system scalability. Compared to the abovementioned wirelessly-powered cage designs which suffer from the size

*Electronics* **2020**, *9*, 1999 mismatch between the Tx and Rx coils, the wirelessly-powered cage in Figure 15d does not have this issue [18]. The coils in the inductive link are geomecally optimized. Besides, the optimum alignment between the Tx and Rx coils is also achieved. In Figure 15d, the IRPower system uses a servocontrolled Tx coil moving under the cage on the X and Y rails. A permanent magnet in the mobile device and an array of magnetic sensors placed around the Tx coil form the animal tracking system.

In Figure 15b, the Tx coil completely encompasses the area in which the animals can roam freely, resulting in an effective space of 40 × 40 × 20 (height) cm<sup>3</sup> [29]. These two designs can improve the WPT resilience to lateral and vertical misalignments between the Tx and Rx coils. However, the angular misalignments still can negatively impact the PTE of the inductive link. Moreover, due to huge size difference, the pair of Tx and Rx coils is away from their optimal size matching, resulting in the low PTE of these two designs. For a larger experimental arena, the size of the Tx coil will be enlarged accordingly, which will aggravate the coil size mismatch and then the PTE reduction. For the designs in Figure 15a,b, the Tx coil covers the 3D volume of the experimental arena, which can ensure the strength of the magnetic field within the covered volume. Given the real-time optimized size and optimized alignment of the Tx and Rx coils, the PTE of this inductive link design is high. The IRPower system in Figure 15d also features a CLPC, which compensates the PDL variations by adjusting the amount of power transmitted into the Tx coil. However, the mechanical setup of and X and Y rails enlarges the size of the IRPower system, making it incompatible with the standard racks of rodent cages in animal facilities. For high throughput experiments, a large number of cages can be located in standard racks in animal research facilities without occupying precious laboratory space. In addition, with the Tx coil underneath the cage, the systems in Figure 15c,d will have the dramatic reduction in the magnetic field strength and then the PTE, as the distance between the Tx and Rx coil increases. Table 2 compares the features of the abovementioned systems. 

**Figure 15.** Examples of wirelessly-powered cage designs with a single Tx coil configuration presented in (**a**) [28], (**b**) [29], (**c**) [30], and (**d**) [18].

For the wirelessly-powered cage design shown in Figure 15c, the Tx coil is located underneath the circular mouse cage with a diameter of 8 inches, and the power Rx is a 15 mm-long, 2 mm-diameter solenoid coil wrapping around a copper ferrite core [30]. The coil size mismatch is eased in this design, at the cost of smaller wirelessly-powered arena, compared to the designs in Figure 15a,b. The Rx coil continuously receivers a large amount of power of 2 W over distances of several centimeters within the cage. Given that the inductive link is non-optimal, it is challenging to ensure the wireless power transmission safety by not overcoming the SAR limitation in the case of strong power delivery. In this wirelessly-powered cage system, the Tx coil also needs to cover the bottom area of the circular mouse cage. Such a configuration is also not conductive for the system scalability.

Compared to the abovementioned wirelessly-powered cage designs which suffer from the size mismatch between the Tx and Rx coils, the wirelessly-powered cage in Figure 15d does not have this issue [18]. The coils in the inductive link are geomecally optimized. Besides, the optimum alignment between the Tx and Rx coils is also achieved. In Figure 15d, the IRPower system uses a servo-controlled Tx coil moving under the cage on the X and Y rails. A permanent magne<sup>t</sup> in the mobile device and

an array of magnetic sensors placed around the Tx coil form the animal tracking system. Given the real-time optimized size and optimized alignment of the Tx and Rx coils, the PTE of this inductive link design is high. The IRPower system in Figure 15d also features a CLPC, which compensates the PDL variations by adjusting the amount of power transmitted into the Tx coil. However, the mechanical setup of and X and Y rails enlarges the size of the IRPower system, making it incompatible with the standard racks of rodent cages in animal facilities. For high throughput experiments, a large number of cages can be located in standard racks in animal research facilities without occupying precious laboratory space. In addition, with the Tx coil underneath the cage, the systems in Figure 15c,d will have the dramatic reduction in the magnetic field strength and then the PTE, as the distance between the Tx and Rx coil increases. Table 2 compares the features of the abovementioned systems.


**Table 2.** Benchmarking of the wirelessly-powered cage systems with a single Tx coil configuration.

#### *3.2. Wirelessly-Powered Cage Systems with a Scalable Tx Coil Array*

With the configuration of the scalable Tx coil array, the wirelessly-powered cage systems introduced in this section have scalable designs [11,17,31]. Each Tx coil in the array has its optimum diameter matched with the Rx coil at a given Rx-Tx separation distance. Within the array, the Tx coil closest to the animal, which is often in the best position to power the mobile unit, is activated. Several different methods have been used to dynamically and automatically activate the Tx coil that is in the optimum alignment with the Rx coil.

The inductive link configuration in Figure 16a includes a single Rx coil embedded in the mobile device and two overlapping arrays of planar Tx coils placed at the bottom of the cage [31]. Every four coils are connected to a single driver module. The 50% overlap in both X and Y directions eliminates dead spots on the power transmission side. Rx tracking is performed by the impedance tracking technique. Particularly, the proximity of the Rx coil will induce a reflected impedance adding onto the Tx coil, causing a reduction in the current drawn from the driver. The Tx power controller detects the impedance variation of each Tx coil by sensing its supply current variation so that the Tx coil closest to the Rx can be identified as the one with supply current reduction.

In Figure 16b, the wirelessly-power cage system includes a resonance-based inductive link with its configuration adjustable [11]. The stationary unit includes a three-layer array of overlapping hex-PSCs that tile the floor of the experimental arena, Tx coils on the third layer driven by PAs and Tx resonators on the first and second layers. The Tx coil can directly link to the mobile unit by forming a three-coil inductive link if the nearest to the Rx is a Tx coil. Otherwise, a four-coil inductive link will be formed if a Tx resonator is closest to the Rx. The animal location tracking is performed via an array of magnetic sensors under the stationary unit and a magnetic tracer in the mobile device. This system is equipped with CLPC, which can enhance the robustness of the wireless power delivery against the Tx-Rx distance variation.

array on the top surface of the cage limits access to the animals and blocks the field of view of video recording for analyzing animal behavior. 

*Electronics* **2020**, *9*, 1999 In sum, the abovementioned wirelessly-powered cage systems feature the modular and scalable architecture, which allows for experimental arenas with arbitrary shapes and dimensions. While the Tx includes multiple coils, these systems can still minimize the power interferences as only one Tx coil is activated at a time. Table 3 compares the features of the abovementioned systems. 

**Figure 16.** Examples of wirelessly-powered cage system designs with the Tx coil array configuration presented in (**a**) [31], (**b**) [11], and (**c**) [17]. **Figure 16.** Examples of wirelessly-powered cage system designs with the Tx coil array configuration presented in (**a**) [31], (**b**) [11], and (**c**) [17].

**Table 3.** Benchmarking of the wirelessly-powered cage systems with scalable Tx coil array configuration. **Publications [31] [11] [17]**  Inductive link 2-coil 3/4-coil 4-coil Frequency 1.5 MHz 13.56 MHz 13.56 MHz WPT coverage, length × width × height 42 × 18 × (8±11) cm3 3538 × 12 cm3 27 × 27 × 16 cm3 Mobile device size, length × width × height 40 × 40 mm2 <sup>Δ</sup> × 202 × 20 mm3 42 mm diameter PTE 13–39% 5.6–12.6% 59% PDL 21–225 mW 20 mW 100 mW CLPC × dž <sup>×</sup> Tx control simplicity × × dž Compatible to racks dž <sup>×</sup>dž Angular misalignment resilience × × dž No view-blocking dž dž <sup>×</sup> Figure 16c shows another wirelessly-powered cage design based on a 13.56 MHz resonance-based four-coil inductive link [17]. The power Tx includes a Tx coil powered by a PA and two arrays of Tx resonators connected in parallel and tiled at the top and bottom surfaces of the chamber to form uniform wireless power distribution in 3D. The top and bottom resonator arrays have more or less contribution to the power transmission, depending on the location of the mobile device in the z-direction. The distance between the surfaces is set for ensuring almost constant power delivery to the mobile device in the z-direction. Such an arrangemen<sup>t</sup> also can improve the system tolerance to angular misalignments, as the Tx resonators at two surfaces will contribute to directing the EM filed towards the mobile device. The Tx resonator array configuration features the natural power localization mechanism that the Tx resonators located directly below and above the mobile device will be automatically activated. Without the requirements of Rx location detection and Tx coil switching, the system implementation can be significantly simplified. However, placing a resonator array on the top surface of the cage limits access to the animals and blocks the field of view of video recording for analyzing animal behavior. In sum, the abovementioned wirelessly-powered cage systems feature the modular and scalable architecture, which allows for experimental arenas with arbitrary shapes and dimensions. While the Tx includes multiple coils, these systems can still minimize the power interferences as only one Tx coil

resonators wrapping around the cage [13,16,32,33]. The slanted Tx resonators help bend and direct the magnetic flux towards the Rx coil. Such a configuration can improve the system tolerance to angular misalignments. Additionally, the geometry of the Tx and Rx coils are optimized and matched, which is beneficial to improve PTE. 

*Electronics* **2020**, *9*, 1999 **Table 3.** Benchmarking of the wirelessly-powered cage systems with scalable Tx coil array configuration. **Publications [31] [11] [17]** Inductive link 2-coil 3/4-coil 4-coil Frequency 1.5 MHz 13.56 MHz 13.56 MHz WPT coverage, length × width × height 42 × 18 × (8–11) cm<sup>3</sup> 3538 × 12 cm<sup>3</sup> 27 × 27 × 16 cm<sup>3</sup> Mobile device size, length × width × height 40 × 40 mm<sup>2</sup> π × 20<sup>2</sup> × 20 mm<sup>3</sup> 42 mm diameter PTE 13–39% 5.6–12.6% 59% PDL 21–225 mW 20 mW 100 mW CLPC × √ × Tx control simplicity × × √ The wirelessly-powered cage system, shown in Figure 17a, is built based on a resonance-based inductive link whose configuration is adjustable [16]. The stationary unit includes one square-shaped central Tx coil at the bottom of the cage and four triangular-shaped slanted Tx resonators on the corners of the cage. The Tx coil can directly form a three-coil inductive link with the coils in the mobile device when the animal moves to the center of the cage, or form a four-coil inductive link with one Tx resonator when the mobile device is at a corner of the cage. The position of the mobile device is tracked in real-time by a Microsoft Kinect installed above the cage. Depending on the recorded position information, the stationary unit will either deactivate all Tx resonators or activate the Tx resonator closest to the mobile device by shorting this Tx resonator with a resonant capacitor for forming an LC-tank with a high quality-factor. However, installing the Microsoft Kinect will enlarge the experimental volume needed for the entire system setup, making the system not compatible to the racks of standard-sized rodent cages. 

Compatible to racks √× √Angular misalignment resilience × × √ No view-blocking √ √ × *3.3. Wirelessly-Powered Cage Systems with Slanted Tx Resonators* The wirelessly-powered cage systems introduced in this section have multiple slanted Tx resonators wrapping around the cage [13,16,32,33]. The slanted Tx resonators help bend and direct the magnetic flux towards the Rx coil. Such a configuration can improve the system tolerance to angular misalignments. Additionally, the geometry of the Tx and Rx coils are optimized and matched, which is beneficial to improve PTE. The wirelessly-powered cage system, shown in Figure 17a, is built based on a resonance-based inductive link whose configuration is adjustable [16]. The stationary unit includes one square-shaped central Tx coil at the bottom of the cage and four triangular-shaped slanted Tx resonators on the corners of the cage. The Tx coil can directly form a three-coil inductive link with the coils in the mobile device when the animal moves to the center of the cage, or form a four-coil inductive link with one Tx resonator when the mobile device is at a corner of the cage. The position of the mobile device is tracked in real-time by a Microsoft Kinect installed above the cage. Depending on the recorded position information, the stationary unit will either deactivate all Tx resonators or activate the Tx resonator closest to the mobile device by shorting this Tx resonator with a resonant capacitor for forming an LC-tank with a high quality-factor. However, installing the Microsoft Kinect will enlarge the experimental volume needed for the entire system setup, making the system not compatible to the racks of standard-sized rodent cages. In Figure 8a, the wirelessly-powered cage system, named EnerCage-HC, includes four-coil inductive link built around a standard-sized rodent cage [13]. The inductive link has a square-shaped Tx coil attached at the center and bottom of the cage and four Tx resonators wrapping around the cage at different heights/orientations, and planar Rx resonator and Rx coil in the mobile device. The slanted Tx resonators, which direct the magnetic field to the mobile device, together with the CLPC can support sufficient and constant PDL up to 80-degree rotation. In Figure 17b,c, two similar wireless cage designs are presented [32,33]. In the wirelessly-powered cage system, shown in Figure 17b, two more Tx resonators, wrapping around the bottom and top rim of the cage, are added to enhance the homogenous distribution of the transmitted power in the z-direction [32]. The Tx coil consists of multiple identical spiral coils connected in series. However, the Tx coil located at the top of the cage may block the line of view of the camera. The wireless cage design, shown in Figure 17c, has a similar Tx resonator configuration [33]. The Tx coil is formed by three identical coils connected in parallel and tiled at the bottom of the cage to make the transmitted power more evenly distributed in 3D. Thanks to the slanted Tx resonators, the abovementioned wirelessly-powered cage systems show improved robustness to the angular misalignment. Additionally, the Tx coil configuration makes the magnetic field more evenly distributed in the 3D volume of the cage, and the required number of PAs is reduced to only one. For the abovementioned four designs, there is no need for Tx resonator switching, significantly reducing the design complexity, and they feature the compatibility to the standard racks. However, the abovementioned wirelessly-powered cage designs are not scalable. The size of the Tx resonators increases as the cage side increases, which will weaken the advantage of promoting EM uniform distribution. Table 4 compares the features of the abovementioned systems. 

**Figure 17.** *Cont.*

**Figure 17.** Examples of wirelessly-powered cage system designs with the slanted Tx resonator configuration presented in (**a**) [16], (**b**) [32], and (**c**) [33]. **Figure 17.** Examples of wirelessly-powered cage system designs with the slanted Tx resonator configuration presented in (**a**) [16], (**b**) [32], and (**c**) [33].

**Table 4.** Benchmarking of the wirelessly-powered cage systems with slanted Tx resonator configuration. **Publications [16] [13] [32] [33]**  Inductive link 3/4-coil 4-coil 4-coil 42-coil Frequency 13.56 MHz 13.56 MHz 13.56 MHz 13.56 MHz WPT coverage, length × width × height 30 × 30 × 17 cm<sup>3</sup> 46 × 24 × 20 cm<sup>3</sup> 28.5 × 18 × 13 cm<sup>3</sup> 46 × 24 × 20 cm<sup>3</sup> Mobile device size, length × width × height. 40 × 40 × 20 mm<sup>3</sup> 20 × 22 × 5 mm<sup>3</sup> 26 × 26 × 35 mm<sup>3</sup> 15 × 15 × 10 mm<sup>2</sup> PTE 16.1–36.3% 14% 34–42% 17% PDL 24 mW 42 mW 13 mW 62 mW CLPC dž dž <sup>×</sup>dž dždžIn Figure 8a, the wirelessly-powered cage system, named EnerCage-HC, includes four-coil inductive link built around a standard-sized rodent cage [13]. The inductive link has a square-shaped Tx coil attached at the center and bottom of the cage and four Tx resonators wrapping around the cage at di fferent heights/orientations, and planar Rx resonator and Rx coil in the mobile device. The slanted Tx resonators, which direct the magnetic field to the mobile device, together with the CLPC can support su fficient and constant PDL up to 80-degree rotation. In Figure 17b,c, two similar wireless cage designs are presented [32,33]. In the wirelessly-powered cage system, shown in Figure 17b, two more Tx resonators, wrapping around the bottom and top rim of the cage, are added to enhance the homogenous distribution of the transmitted power in the z-direction [32]. The Tx coil consists of multiple identical spiral coils connected in series. However, the Tx coil located at the top of the cage may block the line of view of the camera. The wireless cage design, shown in Figure 17c, has a similar Tx resonator configuration [33]. The Tx coil is formed by three identical coils connected in parallel and tiled at the bottom of the cage to make the transmitted power more evenly distributed in 3D.

Tx control simplicity × dž Compatible to racks × dž dž dž No view blocking dž dž <sup>×</sup>dž *3.4. Wirelessly-Powered Cage Systems for Omnidirectional Power Transmission*  In the experiments involving small freely-moving animals, such as rodents, the horizontal, distance, and/or angular misalignments between the power Tx and Rx components may frequently happen due to the animal's free movements. The misalignments will result in a significant reduction in the PTE and the PDL. In this section, we will introduce several omnidirectional power transmission solutions that can address robust wireless power delivery in the presence of any position and/or orientation variations of the Rx device. Thanks to the slanted Tx resonators, the abovementioned wirelessly-powered cage systems show improved robustness to the angular misalignment. Additionally, the Tx coil configuration makes the magnetic field more evenly distributed in the 3D volume of the cage, and the required number of PAs is reduced to only one. For the abovementioned four designs, there is no need for Tx resonator switching, significantly reducing the design complexity, and they feature the compatibility to the standard racks. However, the abovementioned wirelessly-powered cage designs are not scalable. The size of the Tx resonators increases as the cage side increases, which will weaken the advantage of promoting EM uniform distribution. Table 4 compares the features of the abovementioned systems. **Table 4.** Benchmarking of the wirelessly-powered cage systems with slanted Tx resonator configuration.

One omnidirectional power transmission solution is a cavity resonator-based wireless cage design, as shown in Figure 18a [34]. On the power Tx side, the H-field produced is rotational around the center of the cavity. The amplitude of the H-field increases radially from the center to the periphery and is not a function of height. On the Rx side, the implantable device has two Rx coils oriented perpendicular to each other. This placement of the two Rx coils can address the device orientation insensitivity within two planes. To achieve truly omnidirectional powering, a third Rx coil oriented perpendicular to the first two Rx coils should be added. Even then, there are still five WPT blind spots, namely the center and four corners of the cavity, where the H-field is very weak. **Publications [16] [13] [32] [33]** Inductive link 3/4-coil 4-coil 4-coil 42-coil Frequency 13.56 MHz 13.56 MHz 13.56 MHz 13.56 MHz WPT coverage, length × width × height 30 × 30 × 17 cm<sup>3</sup> 46 × 24 × 20 cm<sup>3</sup> 28.5 × 18 × 13 cm<sup>3</sup> 46 × 24 × 20 cm<sup>3</sup> Mobile device size, length × width × height. 40 × 40 × 20 mm<sup>3</sup> 20 × 22 × 5 mm<sup>3</sup> 26 × 26 × 35 mm<sup>3</sup> 15 × 15 × 10 mm<sup>2</sup> PTE 16.1–36.3% 14% 34–42% 17% PDL 24 mW 42 mW 13 mW 62 mW CLPC √ √ × √ Tx control simplicity × √√√ 

For the wirelessly-power cage system, shown in Figure 11, we call it EnerCage-HC2 system [14]. Based on the EnerCage-HC system shown in Figure 8a, the fifth Tx resonator is added at the top rim of the homecage to enhance the magnetic flux density at top of the cage. More importantly, the Rx resonators in the EnerCage-HC2 system encompass four diagonal planes of the mobile device. Such a novel Rx coil arrangement directs the transmitted EM field, which is already homogenized by the Tx resonators, towards the Rx coil at the bottom of the mobile device at any arbitrary orientations. Compatible to racks × √√√No view blocking √ √ × √ 123

#### *3.4. Wirelessly-Powered Cage Systems for Omnidirectional Power Transmission*

In the experiments involving small freely-moving animals, such as rodents, the horizontal, distance, and/or angular misalignments between the power Tx and Rx components may frequently happen due to the animal's free movements. The misalignments will result in a significant reduction in the PTE and the PDL. In this section, we will introduce several omnidirectional power transmission solutions that can address robust wireless power delivery in the presence of any position and/or orientation variations of the Rx device.

One omnidirectional power transmission solution is a cavity resonator-based wireless cage design, as shown in Figure 18a [34]. On the power Tx side, the H-field produced is rotational around the center of the cavity. The amplitude of the H-field increases radially from the center to the periphery and is not a function of height. On the Rx side, the implantable device has two Rx coils oriented perpendicular to each other. This placement of the two Rx coils can address the device orientation insensitivity within two planes. To achieve truly omnidirectional powering, a third Rx coil oriented perpendicular to the first two Rx coils should be added. Even then, there are still five WPT blind spots, namely the center and four corners of the cavity, where the H-field is very weak. *Electronics* **2020**, *9*, x FOR PEER REVIEW 21 of 28 

**Figure 18.** Examples of wirelessly-powered cage systems offering omnidirectional power transmission, presented in (**a**) [34], (**b**) [35], (**c**) [36], and (**d**) [22]. **Figure 18.** Examples of wirelessly-powered cage systems offering omnidirectional power transmission, presented in (**a**) [34], (**b**) [35], (**c**) [36], and (**d**) [22].

**Table 5.** Benchmarking of the wirelessly-powered cage systems offering omnidirectional power transmission. **Publications [34] [14] [35] [36] [22]**  Inductive link Cavity 4-coil 2-coil 2-coil 2-coil Frequency 346.6 MHz 13.56 MHz 6.78 MHz 530 kHz 280 kHz WPT coverage, length × width × height 61 × 61 × 30 cm<sup>3</sup> 46 × 24 × 20 cm<sup>3</sup> 30 × 30 × 30 cm<sup>3</sup> N/A 1 m3 Mobile device size, length × width × height <sup>Δ</sup> × (7)2 × 25 mm<sup>3</sup> 20 × 22 × 11 mm<sup>3</sup> ~64 × 64 × 64 mm<sup>3</sup> N/A 20 × 20 × 0.5 cm3 PTE 14.32% 23.6–33.3% 7.9% N/A 33.6% For the wirelessly-power cage system, shown in Figure 11, we call it EnerCage-HC2 system [14]. Based on the EnerCage-HC system shown in Figure 8a, the fifth Tx resonator is added at the top rim of the homecage to enhance the magnetic flux density at top of the cage. More importantly, the Rx resonators in the EnerCage-HC2 system encompass four diagonal planes of the mobile device. Such a novel Rx coil arrangemen<sup>t</sup> directs the transmitted EM field, which is already homogenized by the Tx resonators, towards the Rx coil at the bottom of the mobile device at any arbitrary orientations. Together with CLPC, the inductive link achieves omnidirectional power delivery to the mobile device, irrespective of the subject's location or head orientation. When the mobile device is 90◦ rotated while locating along the center lines of the homecage, the magnetic fields passing through the two Rx resonators are bent in the opposite direction and cancel with each other. In this case, little magnetic


field can pass through the Rx coil, resulting in PTE drop. It should be noted that the probability of this case happening is quite low in practice. Therefore, we add a small supercapacitor following the rectifier in the mobile device to prevent any sudden drop in the supply voltage.

In addition to the EnerCage-HC2 system, there are three other inductive link configurations that have been proposed to address omnidirectional wireless powering [22,35,36]. One possible coil configuration is a set of triple orthogonal Rx coils together with a single Tx coil. For achieving higher uniformity of magnetic flux, a pair of Tx coils facing each other can be used instead of a single Tx coil. On the Rx side, each Rx coil is followed by an AC-DC converter, such as a rectifier. The three rectifiers can be connected in series or in parallel to drive their common load. In the series connection scenario, the three DC output voltages of the rectifiers are stacked for providing supply voltage for the load. With the parallel connection scheme, the highest Rx coil voltage is automatically delivered to the load. In Figure 18b, two pairs of Tx coils facing each other are attached to the vertical sides of the cage and driven by their own class-D PA simultaneously [35]. On the Rx side, three coils are placed at 90◦ from each other, which can make the system insensitive to angular misalignments. However, the Tx coil configuration causes two "cold corners" formed by opposite magnetic fields and two "hot corners" formed by constructive magnetic fields in the cage. In the "cold corners", the triple orthogonal Rx coils still cannot ensure omnidirectional powering. Besides, the Rx coils block the access to the electronics inside the mobile device, making it difficult to repair or to have electrode feed-through.

The triple orthogonal Tx coils together with a single Rx coil is another coil configuration offering the omnidirectional powering. If the three Tx coils are driven by the same current, a constant magnetic field in a fixed direction will be generated. For omnidirectional powering, the three Tx coil currents should be driven appropriately different from each other in order to generate a rotating magnetic field. To achieve this objective, there are three possible modulation methods in general: (1) phase-domain modulation (PDM); (2) amplitude-domain modulation (ADM); and (3) frequency-domain modulation (FDM). Given the simplicity of implementing system control, the PDM method is widely used. In Figure 18c, the PDM method is used. More specifically, the three Tx coils excited with three-phase currents with a peak magnitude of 250 mA and 120◦ displacement are wound on the outer surface of a glass bowl [36]. The magnetic field vectors rotate periodically in all directions. Three loads hung inside the glass bowl with the Rx coil facing in different directions. Each load consists of a planar Rx coil, a rectifier, and four LEDs. It can be seen that the LEDs in all three loads are on, confirming the omnidirectional nature of the wireless power transmission.

The third viable coil configuration offering omnidirectional powering is the double orthogonal Tx coils together with double orthogonal Rx coils. The two orthogonal Tx coils should be driven by two nonidentical currents to form a rotating magnetic field. Figure 18d shows an example of such a coil configuration [22]. Instead of using loop coils, both the Tx and Rx coil, operating at 280 kHz, have crossed-dipole coil structure. The crossed-dipole Tx and Rx coils are composed of a dual set of two orthogonal coils, wire-wounded around ferromagnetic cores. The currents of the two Tx coils have the same magnitude with a 90◦ phase difference from each other in order to generate a rotating magnetic field. The magnetic field produced can always pass through the crossed-dipole Rx coils at any orientations, to allow for the omnidirectional power receiving. Additionally, the physical dimensions of Tx and Rx are reduced from volume to plane, which is crucial for practical applications, where volumetric coil structure is highly prohibited. Table 5 compares the features of the abovementioned systems for omnidirectional power transmission.

**Table 5.** Benchmarking of the wirelessly-powered cage systems offering omnidirectional power transmission.




coil to maximize its quality factor is within several tens to hundreds of megahertz range. At such high

**4. Designs of Wirelessly-Powered Cage for mm-Sized Implants** operating frequencies, it also increases the risk of unsafe exposure to EM radiation and interference, 

Instead of a single, large, and centralized mobile device [37,38], distributed neural interfaces made of a large number of tiny implants are poised to play a key role in future brain-computer interfaces (BCI) because of their less damage to the surrounding tissue. However, it is challenging to wirelessly operate the tiny implants in a cage. As a result of the significant size di fference, the coupling between the Tx and Rx coils is quite weak. The optimal operating frequency for a mm-sized coil to maximize its quality factor is within several tens to hundreds of megahertz range. At such high operating frequencies, it also increases the risk of unsafe exposure to EM radiation and interference, which, in turn, imposes new challenges on SAR compliance. The misalignments caused by free movements of the animal subject and/or the arbitrary placement of the tiny implants, which combine with the other challenges, make it challenging to maintain su fficient power delivery to the tiny implants within a cage. Thus, it is important to develop WPT systems that can overcome these challenges. which, in turn, imposes new challenges on SAR compliance. The misalignments caused by free movements of the animal subject and/or the arbitrary placement of the tiny implants, which combine with the other challenges, make it challenging to maintain sufficient power delivery to the tiny implants within a cage. Thus, it is important to develop WPT systems that can overcome these challenges. A wireless cage based on the resonant cavity was introduced in [39] to power and control tiny implanted devices. An aluminum resonant cavity, which has 21 cm diameter and 15 cm height with a surface lattice of hexagons (2.5 cm diameter), is utilized to couple EM energy with 1.5 GHz carrier frequency to the tissue of a mouse as shown in Figure 19a. Compared to the conventional inductive power transfer system through direct coupling between two coils, the energy in this system is confined to the mouse placed on the grid due to the resonance excitation of the limited EM field pattern. This system can provide self-tracking wireless power to the tiny implant within the mouse

A wireless cage based on the resonant cavity was introduced in [39] to power and control tiny implanted devices. An aluminum resonant cavity, which has 21 cm diameter and 15 cm height with a surface lattice of hexagons (2.5 cm diameter), is utilized to couple EM energy with 1.5 GHz carrier frequency to the tissue of a mouse as shown in Figure 19a. Compared to the conventional inductive power transfer system through direct coupling between two coils, the energy in this system is confined to the mouse placed on the grid due to the resonance excitation of the limited EM field pattern. This system can provide self-tracking wireless power to the tiny implant within the mouse resulting in no needs of tracking algorithms over the experimental area. Figure 19b shows a schematic of wireless implant for optogenetic stimulation, designed in the size of 10~25 mm3. This light-emitting implants can receive 5.6~15.7 mW with 3.2 W of averaged input power. Although the wireless operation in RF bands are typically susceptible to signal reflection, interference, and absorption by obstructions, the proposed system in [39] has been successfully demonstrated by behavioral testing environments and has shown the possibility of using RF bands for wireless cage applications. resulting in no needs of tracking algorithms over the experimental area. Figure 19b shows a schematic of wireless implant for optogenetic stimulation, designed in the size of 10~25 mm3. This light-emitting implants can receive 5.6~15.7 mW with 3.2 W of averaged input power. Although the wireless operation in RF bands are typically susceptible to signal reflection, interference, and absorption by obstructions, the proposed system in [39] has been successfully demonstrated by behavioral testing environments and has shown the possibility of using RF bands for wireless cage applications. EM WPT at high frequency in the GHz range facilitate the Rx size reduction due to shorter wavelength, but they suffer from difficulties in creating homogeneous WPT in a large experimental arena [40]. The SAR of EM field in the tissue, which mainly consists of water, at high frequencies is rather high [23]. At high frequency, it also increases the risk of unsafe personnel exposure to EM radiation and interference with nearby instruments [40]. The microwave chamber delivers power at low efficiency through the animal body. Its extension to larger animals and eventually humans without surpassing SAR limits at this frequency does not seem to be feasible, even though it might be a reasonable solution for ultra-low-power applications.

**Figure 19.** (**a**) A diagram of wirelessly-powered cage system, and (**b**) a schematic of wireless implant customized for the brain in [39]. **Figure 19.** (**a**) A diagram of wirelessly-powered cage system, and (**b**) a schematic of wireless implant customized for the brain in [39].

To address this issue, Figure 20 shows the wireless cage for powering tiny implants using inductive coupling at 13.56 MHz frequency with near-field communication hardware [41]. The wireless cage equips a double-loop coil with turns at heights of 4 and 11 cm from the bottom of the animal enclosure as shown in Figure 20a. This technique is similar with the design in Figure 15a, which improves the inductive coupling at further distance from the bottom of the cage resulting in hifilhhihidThil303011d126

EM WPT at high frequency in the GHz range facilitate the Rx size reduction due to shorter wavelength, but they su ffer from di fficulties in creating homogeneous WPT in a large experimental arena [40]. The SAR of EM field in the tissue, which mainly consists of water, at high frequencies is rather high [23]. At high frequency, it also increases the risk of unsafe personnel exposure to EM radiation and interference with nearby instruments [40]. The microwave chamber delivers power at low e fficiency through the animal body. Its extension to larger animals and eventually humans without surpassing SAR limits at this frequency does not seem to be feasible, even though it might be a reasonablesolutionforultra-low-powerapplications.*Electronics* **2020**, *9*, x FOR PEER REVIEW 23 of 28 normalized received power in the implant decreases to 0~0.9 for 80° angular misalignment. The height for wireless coverage and its uniformity in coverage can be optimized for a given experimental 

 To address this issue, Figure 20 shows the wireless cage for powering tiny implants using inductive at13.56MHzwithnear-fieldcommunicationhardware[41].Thewirelessarea based on the separation of double-loop coil. 

coupling frequency cage equips a double-loop coil with turns at heights of 4 and 11 cm from the bottom of the animal enclosure as shown in Figure 20a. This technique is similar with the design in Figure 15a, which improves the inductive coupling at further distance from the bottom of the cage resulting in the extension of wireless coverage to the higher side. The wireless cage covers 30 × 30 × 11 cm and the power is relatively uniform across the region of interest as shown in Figure 20b although the normalized received power in the implant decreases to 0~0.9 for 80◦ angular misalignment. The height for wireless coverage and its uniformity in coverage can be optimized for a given experimental area based on the separation of double-loop coil. While the wireless cage with high frequency is typically suffer from the SAR in the tissue, the wireless cage in the near-field regime has a difficulty in the reduction of Rx size due to the poor EM field focusing. In Figure 20b, the two-coil inductive link configuration results in the Rx coil with a diameter of 9.8 mm, which becomes the main limiting factor in the device miniaturization. In addition, the single Tx coil configuration, which can simplify the design of the power control circuitry, suffers from low PTE at the center of the cage. Therefore, they transmitted a large amount of power to energize the entire cage. This will result in excessive heat dissipation and large EM interference between the cage and other lab instruments. 

**Figure 20.** (**a**) Simulated normalized output power inside the wireless cage without angular misalignment, and (**b**) wireless operation of 13 implants, placed at height of 3 cm from the bottom [41]. **Figure 20.** (**a**) Simulated normalized output power inside the wireless cage without angular misalignment, and (**b**) wireless operation of 13 implants, placed at height of 3 cm from the bottom [41].

 While the wireless cage with high frequency is typically su ffer from the SAR in the tissue,

In Figure 21a, the dual-band EnerCage-HC system, built upon the EnerCage-HC2 system (Figure 11), uses a two-stage inductive power transmission technique to wirelessly deliver sufficient PDL to the tiny implant within the cage [42]. Given the mismatch between the optimal operating frequencies of the Tx and Rx coils due to their size difference, the dual-band EnerCage-HC system includes two inductive links operating simultaneously at their optimal frequencies. To do so, this system also includes an intermediate unit (a headstage device) in addition to the power Tx and Rx. This intermediate unit acts as a power converter, which receives power from the cage via a four-coil inductive link at 13.56 MHz and delivers it to the tiny implant via a three-coil inductive link at 60 MHz. This intermediate unit is also used as a power buffer that uses its stored energy to support the continuous operation of the tiny implants in the presence of misalignments in the four-coil inductive link. A dual-loop sequential CLPC mechanism, which includes two loops, further stabilizes the amount of power delivered to the tiny implant despite any misalignments by adjusting PDLs of the four-coil inductive link and the three-coil inductive link at designated levels, respectively. Figure 21b shows the final in vitro measurement setup for enabling optical stimulation in the dual-band EnerCage-HC system. The experiment was performed on 6 × 6 × 7 cm cube from a fresh sheep head, including brain, skull, fat, and skin, and placed the cube in the center of the cage. The headstage was mounted on top of the tissue cube to receive 13.56 MHz carrier from the EnerCage-HC coils while the mm-sized implant was placed ~2 mm under the skull. It shows both the orange LED that is an indicatoroftheheadstagereceivingsufficientpowerat1356MHzandtheselectedΐLED(bluethe wireless cage in the near-field regime has a di fficulty in the reduction of Rx size due to the poor EM field focusing. In Figure 20b, the two-coil inductive link configuration results in the Rx coil with a diameter of 9.8 mm, which becomes the main limiting factor in the device miniaturization. In addition, the single Tx coil configuration, which can simplify the design of the power control circuitry, su ffers from low PTE at the center of the cage. Therefore, they transmitted a large amount of power to energize the entire cage. This will result in excessive heat dissipation and large EM interference between the cage and other lab instruments. In Figure 21a, the dual-band EnerCage-HC system, built upon the EnerCage-HC2 system (Figure 11), uses a two-stage inductive power transmission technique to wirelessly deliver sufficient PDL to the tiny implant within the cage [42]. Given the mismatch between the optimal operating frequencies of the Tx and Rx coils due to their size difference, the dual-band EnerCage-HC system includes two inductive links operating simultaneously at their optimal frequencies. To do so, this system also includes an intermediate unit (a headstage device) in addition to the power Tx and Rx. This intermediate unit acts as a power converter, which receives power from the cage via a four-coil inductive link at 13.56 MHz and delivers it to the tiny implant via a three-coil inductive link at 60 MHz. This intermediate unit is also used as 127

a power buffer that uses its stored energy to support the continuous operation of the tiny implants in the presence of misalignments in the four-coil inductive link. A dual-loop sequential CLPC mechanism, which includes two loops, further stabilizes the amount of power delivered to the tiny implant despite any misalignments by adjusting PDLs of the four-coil inductive link and the three-coil inductive link at designated levels, respectively. Figure 21b shows the final in vitro measurement setup for enabling optical stimulation in the dual-band EnerCage-HC system. The experiment was performed on 6 × 6 × 7 cm cube from a fresh sheep head, including brain, skull, fat, and skin, and placed the cube in the center of the cage. The headstage was mounted on top of the tissue cube to receive 13.56 MHz carrier from the EnerCage-HC coils while the mm-sized implant was placed ~2 mm under the skull. It shows both the orange LED that is an indicator of the headstage receiving sufficient power at 13.56 MHz, and the selected μLED (blue color) for optogenetic stimulation that is powered at 60 MHz. *Electronics* **2020**, *9*, x FOR PEER REVIEW 24 of 28

**Figure 21.** A prototype of inductive power transfer systems for tiny implants, proposed in [42] for (**a**) conceptual system overview and (**b**) in vitro measurement setup. **Figure 21.** A prototype of inductive power transfer systems for tiny implants, proposed in [42] for (**a**) conceptual system overview and (**b**) in vitro measurement setup.

Figure 22a presents a new wireless power transfer system that can wirelessly power a large number of tiny implants arbitrarily distributed over a large tissue area. This is achieved by a power Tx platform which can generate a vertical and lateral magnetic field alternately at any places within the experimental arena [21]. This power Tx platform includes three overlapping layers of hex-PSCs tiled at the bottom of the cage. The three layers are horizontally shifted in a way that the centers of every three adjacent hex-PSCs on three different layers are on the corners of an equilateral triangle. In each layer, every three adjacent hex-PSCs are driven at carrier signals with the same magnitude and phase of 0°, 120°, and 240°, respectively, as shown in Figure 22b. To avoid any counteracts among the three layers, they are controlled by time-division multiplexing (TDM). The appropriate TDM period, *T*, is decided by the carrier frequency, time constant of the capacitance following the Rx coil and rectifier, Rx loading, and the acceptable level of ripple on the regulated supply voltage of the electronics that are powered by the Rx coil as shown in Figure 22c. To this end, this power Tx platform in Figure 22d, which takes advantage of the overlapping placements of the three layers, the threephase power carrier signals, and the TDM control mechanism, eventually achieves omnidirectional WPT towards a large number of tiny implants with arbitrary angular and/or spatial misalignments. In the measured result, the proposed method in [21] achieves 5% of PTE distributions and 5 mW of PDL within the area for 90° angular misalignment of Rx coil compared to 0.8% of PTE for the conventional WPT system. Figure 22a presents a new wireless power transfer system that can wirelessly power a large number of tiny implants arbitrarily distributed over a large tissue area. This is achieved by a power Tx platform which can generate a vertical and lateral magnetic field alternately at any places within the experimental arena [21]. This power Tx platform includes three overlapping layers of hex-PSCs tiled at the bottom of the cage. The three layers are horizontally shifted in a way that the centers of every three adjacent hex-PSCs on three different layers are on the corners of an equilateral triangle. In each layer, every three adjacent hex-PSCs are driven at carrier signals with the same magnitude and phase of 0◦, 120◦, and 240◦, respectively, as shown in Figure 22b. To avoid any counteracts among the three layers, they are controlled by time-division multiplexing (TDM). The appropriate TDM period, *T*, is decided by the carrier frequency, time constant of the capacitance following the Rx coil and rectifier, Rx loading, and the acceptable level of ripple on the regulated supply voltage of the electronics that are powered by the Rx coil as shown in Figure 22c. To this end, this power Tx platform in Figure 22d, which takes advantage of the overlapping placements of the three layers, the three-phase power carrier signals, and the TDM control mechanism, eventually achieves omnidirectional WPT towards a large number of tiny implants with arbitrary angular and/or spatial misalignments. In the measured result, the proposed method in [21] achieves 5% of PTE distributions and 5 mW of PDL within the area for 90◦ angularmisalignmentofRxcoilcomparedto0.8%ofPTEfortheconventionalWPTsystem.

 (**b**)

(**a**)

*Electronics* **2020**, *9*, 1999 in Figure 22d, which takes advantage of the overlapping placements of the three layers, the threephase power carrier signals, and the TDM control mechanism, eventually achieves omnidirectional WPT towards a large number of tiny implants with arbitrary angular and/or spatial misalignments. In the measured result, the proposed method in [21] achieves 5% of PTE distributions and 5 mW of PDL within the area for 90° angular misalignment of Rx coil compared to 0.8% of PTE for the conventional WPT system. 

**Figure 22.** (**a**) Rendered view of distributed BCI concept, (**b**) phase distribution among the hex-PSCs in one conductive layer, (**c**) TDM driving techniques to avoid the magnetic interference between three layers, and (**d**) a prototype measurement setup for the three-phase TDM overlapping hex-PSC array in [21]. **Figure 22.** (**a**) Rendered view of distributed BCI concept, (**b**) phase distribution among the hex-PSCs in one conductive layer, (**c**) TDM driving techniques to avoid the magnetic interference between three layers, and (**d**) a prototype measurement setup for the three-phase TDM overlapping hex-PSC array in [21].

**5. Conclusions**

**5. Conclusions**  Wirelessly-powered cages for IMD applications are categorized and discussed with their key techniques, such as closed-loop power control, coil design/optimization, scalability for wireless coverage, spatial/angular misalignments, near-field data telemetry, and safety issues. Since the highperformance IMDs mainly focus on long-term recording and stimulation functionalities for central and peripheral nervous systems on freely behaving animal subjects [37,38], it is important to design a suitable wireless power platform covering a large experimental arena. Different techniques for wirelessly-powered cages that are benchmarked in Tables 2–5 consider various practical issues described in this article. Although most wirelessly-powered cages provide PTE and PDL for specific experimental conditions, the physical constraints of Rx coils, coil separations, and magnetic field homogeneity over the experimental area should be compared for a more suitable choice. As the most recent class of IMDs are millimeter-sized and distributed over a large area in the brain or the rest of the body [43–45], the importance of wirelessly-powered cages for tiny multiple implants is elevated as introduced in Section 4. Hence, it is important for designers to select suitable wirelessly-powered cages, considering the practical limitations of IMD design related to key aspects, such as PTE, PDL, closed-loop power control, scalability, spatial/angular misalignment, near-field data telemetry, and safety issues against various perturbations during the longitudinal animal experiment. With respect to various IMD applications from conventional implantable devices to recent mm-sized implants, this article contributes the design strategy of the appropriate wirelessly-powered cage designs, which have the ability to create an automated enriched environment inside the experimental arena for longterm electrophysiology experiments. Wirelessly-powered cages for IMD applications are categorized and discussed with their key techniques, such as closed-loop power control, coil design/optimization, scalability for wireless coverage, spatial/angular misalignments, near-field data telemetry, and safety issues. Since the high-performance IMDs mainly focus on long-term recording and stimulation functionalities for central and peripheral nervous systems on freely behaving animal subjects [37,38], it is important to design a suitable wireless power platform covering a large experimental arena. Di fferent techniques for wirelessly-powered cages that are benchmarked in Tables 2–5 consider various practical issues described in this article. Although most wirelessly-powered cages provide PTE and PDL for specific experimental conditions, the physical constraints of Rx coils, coil separations, and magnetic field homogeneity over the experimental area should be compared for a more suitable choice. As the most recent class of IMDs are millimeter-sized and distributed over a large area in the brain or the rest of the body [43–46], the importance of wirelessly-powered cages for tiny multiple implants is elevated as introduced in Section 4. Hence, it is important for designers to select suitable wirelessly-powered cages, considering the practical limitations of IMD design related to key aspects, such as PTE, PDL, closed-loop power control, scalability, spatial/angular misalignment, near-field data telemetry, and safety issues against various perturbations during the longitudinal animal experiment. With respect to various IMD applications from conventional implantable devices to recent mm-sized implants, this article contributes the design strategy of the appropriate wirelessly-powered cage designs, which have the ability to create an automated enriched environment inside the experimental arena for long-term electrophysiology experiments.

**Author Contributions:** Conceptualization: B.L. and Y.J.; methodology: B.L. and Y.J.; validation: B.L. and Y.J.; formal analysis: B.L. and Y.J.; investigation: B.L. and Y.J.; data curation: B.L. and Y.J.; writing—original-draft preparation: B.L. and Y.J.; writing—review and editing: B.L. and Y.J.; visualization: B.L. and Y.J.; supervision, project administration, and funding acquisition: B.L. and Y.J. All authors have read and agreed to the published version of the manuscript. 129

**Author Contributions:** Conceptualization: B.L. and Y.J.; methodology: B.L. and Y.J.; validation: B.L. and Y.J.; formal analysis: B.L. and Y.J.; investigation: B.L. and Y.J.; data curation: B.L. and Y.J.; writing—original-draft preparation: B.L. and Y.J.; writing—review and editing: B.L. and Y.J.; visualization: B.L. and Y.J.; supervision, project administration, and funding acquisition: B.L. and Y.J. All authors have read and agreed to the published version of the manuscript.

**Funding:** This work was supported by the Incheon National University (#2019-0299) research gran<sup>t</sup> in 2019.

**Conflicts of Interest:** The authors declare no conflict of interest.
