The disclosure relates generally to radio-frequency (RF) apparatus and methods. More particularly, the disclosure relates to RF apparatus with integrated antenna control, and associated methods.
With the increasing proliferation of wireless technology, such as Wi-Fi, Bluetooth, and mobile or wireless Internet of things (IoT) devices, more devices or systems incorporate RF circuitry, such as receivers and/or transmitters. To reduce the cost, size, and bill of materials, and to increase the reliability of such devices or systems, various circuits or functions have been integrated into integrated circuits (ICs). For example, ICs typically include receiver and/or transmitter circuitry.
In a radio receiver (or transmitter), having two receive (or transmit) antennae can improve reception (or transmission). In one form, a “diversity” receiver can selects one antenna from a group of antennae, for example, two antennae, based on some pre-determined criterion. In typical implementations of antenna diversity, an off-chip (not integrated) antenna switch and/or front-end module (FEM) is controlled by the radio IC.
The description in this section and any corresponding figure(s) are included as background information materials. The materials in this section should not be considered as an admission that such materials constitute prior art to the present patent application.
A variety of apparatus and associated methods are contemplated according to exemplary embodiments. According to one exemplary embodiment, an apparatus includes a first IC that includes a first RF circuit to process RF signals, a first antenna port to couple to one or more antennas, and a first switch integrated in the first IC and coupled to the first antenna port. The apparatus further includes a second IC that includes a second RF circuit to process RF signals, a second antenna port to couple to the one or more antennas, and a second switch integrated in the second IC and coupled to the second antenna port.
According to another exemplary embodiment, an apparatus includes a first IC, which includes a first RF circuit to process RF signals. The first IC further includes a first switch, integrated in the first IC and coupled to an antenna port of the first IC, in order to share at least one antenna coupled to the antenna port of the first IC.
According to another exemplary embodiment, a method of sharing at least one antenna between a first IC having a first switch integrated in the first IC and coupled to a first antenna port, and a second IC having a second switch integrated in the second IC and coupled to a second antenna port, includes closing the first switch to couple the at least one antenna to the second IC. The method further includes opening the second switch to in order for RF circuitry in the second IC to use the at least first antenna.
The appended drawings illustrate only exemplary embodiments and therefore should not be considered as limiting the scope of the application or the claims. Persons of ordinary skill in the art appreciate that the disclosed concepts lend themselves to other equally effective embodiments. In the drawings, the same numeral designators used in more than one drawing denote the same, similar, or equivalent functionality, components, or blocks.
The disclosed concepts relate generally to RF apparatus. More specifically, the disclosed concepts relate to RF apparatus with integrated antenna control, and associated methods. In exemplary embodiments, an IC includes within it integrated control circuitry, antenna interface circuitry, and/or switches that interface with two or more antennae in an antenna diversity scheme.
In a radio receiver (and/or transmitter), having two receive (and/or transmit) antennae can improve reception (and/or transmission). In typical implementations of antenna diversity, an off-chip antenna switch and/or front-end module (FEM) is controlled by a controller. The controller may reside in the same IC as does the RF circuitry. For example, one (or more) general-purpose input/output (GPIO) on the IC may be used to control the antenna diversity switch(es) from the radio IC.
Antenna diversity implementations according to exemplary embodiments eliminate the external FEM or switches. More specifically, in exemplary embodiments, the antenna selection switching and related control are integrated within the same IC that includes the RF circuitry (receive and/or transmit circuitry).
Various embodiments according to the disclosure provide a number of advantages over conventional approaches. For example, integrating the control circuitry, antenna interface circuitry, and/or switches within the IC eliminates the use of off-chip circuitry or components. Furthermore, elimination of the off-chip circuitry or components results in saving one or more package pins of the IC (that would ordinarily be used to control off-chip circuitry/components). In addition, reducing the number and size of the components as a result of the increased integration reduces the overall size, cost, and bill-of-materials for the circuit, block, sub-system, or system in which the RF circuit or device resides.
Note that
As noted, in some embodiments, receive circuits 145 are used in order to receive and process RF signals via one of antennae 110 and 115. When used in exemplary embodiments, receive circuits 145 may include a variety of circuits, such as downconverters, analog-to-digital converters (ADCs), digital-to-analog converters (DACs), decoders, demodulators, error-correction circuitry, amplifiers (including low-noise amplifiers (LNAs), signal sources (such as frequency synthesizers), and the like, as persons of ordinary skill in the art will understand. The choice of circuits included or used in receive circuits 145 depends on factors such as design and performance specifications, intended use, cost and performance goals, etc., as persons of ordinary skill in the art will understand.
As noted, in some embodiments, transmit circuits 150 is used in order to process and transmit RF signals via one of antennae 110 and 115. When used in exemplary embodiments, transmit circuits 150 may include a variety of circuits, such as upconverters, analog-to-digital converters (ADCs), digital-to-analog converters (DACs), encoders, modulators, amplifiers (including power amplifiers (PAs), signal sources (such as frequency synthesizers), and the like, as persons of ordinary skill in the art will understand. The choice of circuits included or used in transmit circuits 150 depends on factors such as design and performance specifications, intended use, cost and performance goals, etc., as persons of ordinary skill in the art will understand.
Receive circuits 145 and/or transmit circuits 150 are coupled to antenna 110 and antenna 115 via balun 130. Specifically, receive circuits 145 and/or transmit circuits 150 are coupled to one port of balun 130. A second port of balun 130 couples to antenna 110 and antenna 115. The second port of balun 130 also couples to switch 120 and to switch 125.
More specifically, one node of the second port of balun 130 couples to antenna 110 and to switch 120. Switch 120, when closed, blocks antenna 110 or, stated another way, shorts to ground the signal to/from antenna 110. When open, however, switch 120 allows the signal to/from antenna 110 to couple to receive circuits 145 and/or transmit circuits 150. Thus, if receive circuits 145 are used, the signal from antenna 110 is provided to receive circuits 145 via balun 130. If transmit circuits 150 are used, the signal from transmit circuits 150 is provided to antenna 110 via balun 130.
Similarly, another node of the second port of balun 130 couples to antenna 115 and to switch 125. When closed, switch 125 blocks antenna 115. Put another way, when closed, switch 125 shorts to ground the signal to/from antenna 115. On the other hand, when open, switch 125 allows the signal to/from antenna 115 to couple to receive circuits 145 and/or transmit circuits 150. If receive circuits 145 are used, the signal from antenna 115 is provided to receive circuits 145 via balun 130. If transmit circuits 150 are used, the signal from transmit circuits 150 is provided to antenna 115 via balun 130.
A controller 135 controls the operation of switch 120 and switch 125. More specifically, controller 135 opens and closes switch 120 and switch 125 in order to select antenna 110 or antenna 115 to receive or transmit RF signals (i.e., by using receive circuits 145 or transmit circuits 150, respectively, in RF circuitry 140).
For example, suppose that one seeks to receive RF signals via antenna 110. Controller 135 causes switch 120 to open, and switch 125 to close. As noted, when closed, switch 125 blocks antenna 115, i.e., shorts to ground the signal from antenna 115. As a result, the RF signal from antenna 110 is provided to RF circuitry 140 (more specifically to receive circuits 145) via balun 130.
As another example, a similar scenario may be used to transmit RF signals from antenna 110. In this situation, controller 135 causes switch 120 to open, and switch 125 to close. When closed, switch 125 blocks antenna 115, i.e., shorts to ground the signal that would otherwise reach antenna 115. As a result, the RF signal from RF circuitry 140 (more specifically from transmit circuits 150) is provided to antenna 110 via balun 130.
Conversely, controller 135 may control switch 110 and switch 115 in a similar manner in order to use antenna 115, rather than antenna 110. For instance, suppose that one seeks to receive RF signals via antenna 115. To accomplish that goal, controller 135 causes switch 125 to open, and switch 120 to close. As noted, when closed, switch 120 blocks antenna 110, i.e., shorts to ground the signal from antenna 110. Consequently, the RF signal from antenna 115 is provided to RF circuitry 140 (more specifically to receive circuits 145) via balun 130.
As another example, suppose that one seeks to transmit RF signals from antenna 115. To do so, controller 135 causes switch 125 to open, and switch 120 to close. By virtue of switch 120 being closed, it blocks antenna 110, i.e., shorts to ground the signal that would otherwise reach antenna 110. As a result, the RF signal from RF circuitry 140 (more specifically from transmit circuits 150) is provided to antenna 115 via balun 130.
Thus, using switch 120 and switch 125 allows shorting to ground an antenna path corresponding to an unselected antenna, as described above. Doing so allows the antenna path corresponding to the selected antenna to be enabled and for the selected antenna to be available for reception or transmission, as desired. Furthermore, note that the active or selected antenna path does not pass through any switches, which provides higher linearity and lower noise compared to the case where switches (e.g., external to IC 105) are used to connect or disconnect the antennae from IC 105.
Generally speaking, a variety of balun configurations may be used, as desired. The choice of the type and configuration of the balun depends on a variety of factors, as persons of ordinary skill in the art will understand. Such factors include performance and design considerations for IC 105, cost, IC die area, available fabrication technology, ease of design, manufacturing, and/or testing, etc.
Note that the first port of balun 130 couples to RF circuitry 150 in a balanced configuration. Conversely, the second port of balun 130 couples to antenna 110 or antenna 115 in an unbalanced configuration. More specifically, to select one of antenna 110 and antenna 115 to receive RF signals or to transmit RF signals, one of switches 120 and 125 is opened, and the other of switches 120 and 125 is closed. As a result, the second port of balun 130 is coupled to the selected antenna in an unbalanced configuration.
In some embodiments, balun 130 includes a transformer. In such a scenario, receive circuits 145 and/or transmit circuits 150 are coupled to one winding or side of the transformer, say, the primary or primary winding. Similarly, antenna 110, antenna 115, switch 120, and switch 125 are coupled to the other winding or side of the transformer, in this example, the secondary or secondary winding. In effect, in the example described, the balun constitutes a two-port network, with the primary and secondary sides or windings of the transformer corresponding to the first and second ports of the two-port network, respectively.
Note that, in some embodiments, rather than using a transformer-based balun 130 as shown in
As noted above, by using controller 135, antenna 110 or antenna 115 may be used for RF signal reception or transmission as part of an antenna diversity scheme. In exemplary embodiments, the selection of antenna 110 or antenna 115 by controller 135 may be performed in variety of ways.
For instance, in some embodiments, during power-up or configuration of IC 105, controller 135 may be instructed or programmed or configured to use antenna 110 or antenna 115. As another example, alternatively or in addition, controller 135 may be instructed or programmed or configured to use antenna 110 or antenna 115 during use of IC 105, for example, in response to instructions by a user of IC 105 or another block or circuit or subsystem in a system or apparatus that uses or includes IC 105.
As another example, controller 135 may select antenna 110 or antenna 115 dynamically during operation of IC 105, based on one or more criteria. The selected antenna may be used to receive RF signals, to transmit RF signals, or both, as desired.
An example of antenna selection criteria may include signal strength. More specifically, receiver circuits 145 may receive an RF signal using antenna 110 and also using antenna 115. The strength (level, power, received signal strength indication (RSSI), etc.) of the received RF signal when using antenna 110 may be compared to the strength of the received RF signal when using antenna 115. The antenna corresponding to the stronger received RF signal may then be selected and used for further RF signal reception.
In some embodiments, the selected antenna may also be used for RF signal transmission, as desired. In other embodiments, one or more different or additional criteria may be used to select an antenna for RF signal transmission, as desired.
For example, an antenna may be selected, and an RF signal transmitted using that antenna. An assessment of the strength of a received signal corresponding to the transmitted signal may be made (e.g., by a remote receiver). This operation may be repeated by selecting and using the other antenna. Depending on which of the received signals corresponding to antenna 110 and antenna 115 is stronger, antenna 110 or antenna 115 may be used for additional RF signal transmission.
Note that
As another example, in some embodiments, RF signal transmission capability, but not RF signal reception capability, may be desired. In such embodiments, receive circuits 145 may be omitted, and transmit circuits 150 may be used for RF signal transmission.
Whether IC 105 includes RF reception capability, RF transmission capability, or both, the antenna control circuitry that includes switch 120 and switch 125 may be used advantageously, as described. Similar considerations and comments apply to the circuit arrangements in
Another aspect of the disclosure relates to using matching networks, sometimes called impedance matching networks, with antenna control circuitry. The matching networks provide a mechanism for coupling together circuitry or blocks of circuitry that might otherwise have impedance mismatches.
For example, an antenna might present a given characteristic impedance, say, Zant, whereas RF circuitry 140 (whether receive circuits 145 or transmit circuits 150, or both) might have a characteristic impedance ZRF, with a complex conjugate ZRF*. As persons of ordinary skill in the art understand, to achieve maximum power transfer to/from such an antenna to/from RF circuitry (at radio frequencies, designers often seek to reduce power loss and maximize power transfer), the following relationship should hold:
Z
ant
=Z
RF*.
If, by virtue of their design or characteristics, the antenna and RF circuitry 140 have difference characteristic impedances, i.e., Zant≠ZRF*, one or more matching networks may be used in order to match Zant to ZRF*. The matching networks typically are coupled between the devices or circuits (or to the devices or circuits) that have differing impedances, such as the antenna and RF circuitry 140, in the above example.
More specifically, referring to
Similarly, LC matching and harmonic filtering networks 230 and 240 are coupled between antenna 115 and balun 130. LC matching and harmonic filtering networks 230 and 240 provide impedance matching between antenna 115 and balun 130. In addition, LC matching and harmonic filtering networks 230 and 240 may provide filtering of harmonic signals (or other spurious or undesired signals) in the signal path between antenna 115 and balun 130.
Circuit arrangement 200 further includes matching network 220. Matching network 220 couples to PA 215 and balun 130, and provides impedance matching between them. Transmit circuits 150 drive PA 215 during the transmit mode of the apparatus in
In addition, circuit arrangement 200 includes matching network 210. Matching network 210 is coupled between balun 130 and LNA 205, and provides impedance matching between them. LNA 205 amplifies the RF signal received from balun 130, and provides the amplified RF signal to receive circuits 145 during the receive mode of the apparatus in
More specifically, in the embodiment shown in
Capacitor 305 is used as another part of the matching network. Capacitor 305 is coupled across the second port of balun 130. Together with LC matching and harmonic filter 235 and LC matching and harmonic filter 240, capacitor 305 provides impedance matching between antennae 110 and 115 and balun 130.
Note that PA 215 in
Circuit arrangement 300 shows three PA slices 215A, 215B, and 215C. As persons of ordinary skill in the art will understand, however, other numbers of PA slices may be used, depending on factors such as desired power levels, design and performance specifications, available technology, etc.
Circuit arrangement 300 shows receive path circuitry (labeled as “RX path circuitry”) 310, which includes receive circuits 145 and RSSI circuit 315. RSSI circuit 315 determines a signal strength of the RF signal received by receive circuits 145 via a selected one of antennae 110-115. RSSI circuit 315 provides an indication of the received signal strength to controller 135. Controller 135 may use the information or indication of the received signal strength as a criterion in selecting one of antennae 110-115 by using switches 120-125, as described above in detail.
As noted above, RF circuitry 140 in
One aspect of the disclosure relates to providing integrated antenna control where one or more blocks of circuitry in RF circuits 140 does not operate in a balanced manner
More specifically, the receive path of the apparatus shown in
LNAs 205A and 205B may be powered selectively, depending on which of antennae 110-115 is used. More specifically, when antenna 110 is selected and used (by closing switch 125 and opening switch 120), LNA 205A may be powered to receive and amplify the RF signal that antenna 110 provides. LNA 205B may be powered down (e.g., by using biasing circuitry or a switch (not shown)) as desired to reduce the power consumption of IC 105.
Conversely, when antenna 115 is selected and used (by closing switch 120 and opening switch 125), LNA 205B may be powered to receive and amplify the RF signal from antenna 115. LNA 205A, however, may be powered down (e.g., by using biasing circuitry or a switch (not shown)) as desired to reduce the power consumption of IC 105.
Furthermore, circuit arrangement 400 uses a multiplexer (MUX) 405 to route the output signals of LNAs 205A-205B to receive circuits 145. More specifically, in response to a control signal from controller 135, MUX 405 routes selectively either the output signal of LNA 205A or the output signal of LNA 205B to receive circuits 145. Receive circuits 145 processes the received RF signal (from LNA 205A or LNA 205B), as discussed above.
Although circuit arrangement 400 illustrates the situation where the receive path of the apparatus in
More specifically, in the embodiment shown in
Capacitor 305 is used as another matching network. Capacitor 305 is coupled across the second port of balun 130. Together with LC matching and harmonic filter 235 and LC matching and harmonic filter 240, capacitor 305 provides impedance matching between antennae 110-115 and balun 130.
Furthermore, LC matching network 210A (see
Note that, similar to the PA in
Circuit arrangement 500 shows three PA slices 215A, 215B, and 215C. As persons of ordinary skill in the art will understand, however, other numbers of PA slices may be used, depending on factors such as desired power levels, design and performance specifications, available technology, etc.
Circuit arrangement 500 shows receive path circuitry 310, which includes receive circuits 145 and RSSI circuit 315. RSSI circuit 315 determines a signal strength of the RF signal received by receive circuits 145 via a selected one of antennae 110-115. RSSI circuit 315 provides an indication of the received signal strength to controller 135. Controller 135 may use the information or indication of the received signal strength as a criterion in selecting one of antennae 110-115 by using switches 120-125, as described above in detail.
Another aspect of the disclosure relates to using integrated antenna control with RF apparatus that uses one antenna, rather than multiple antennae.
Circuit arrangement 600 includes antenna 110, which couples to IC 105 via FEM 605. In the embodiment shown, FEM 605 includes LNA 615 and PA 610. Using LNA 615 provides a gain block in closer proximity to antenna 110 (than, say, using an LNA in IC 105). As a result, the noise figure of circuit arrangement 600 during the receive mode of operation improves.
Furthermore, in the embodiment shown, FEM 605 includes PA 610. PA 610 may be used to provide higher transmit power in situations where the user of the apparatus desired more transmit power than PA 215 provides.
In some embodiments, LNA 615 and PA 610 are implemented in FEM 605 using III-VI semiconductor technologies. As persons of ordinary skill in the art will understand, however, other semiconductor technologies may be used, as desired. The choice of semiconductor technology depends on factors such as available technology, cost, desired performance specifications, and the like.
Referring to
More specifically, controller 135 sends a control signal to FEM 605 via GPIO port 625 (or other port or coupling mechanism between IC 105 and FEM 605, as desired). When RF signal transmission is desired, controller 135 causes switch 120 to close and switch 125 to open. As a result, RF signals from PA 215 are routed to FEM 605 via balun 130, matching network 230, and matching network 240.
The transmit signal from IC 105 (e.g., via matching network 240) to PA 610. Under control of controller 135, switch 620 in FEM 605 couples the output of PA 610 to antenna 110. Consequently, RF signals are transmitted via antenna 110.
Conversely, when RF signal reception is desired, under control of controller 135, switch 620 in FEM 605 couples antenna 110 to the input of LNA 615. Controller 135 further causes switch 120 to open and switch 125 to close. As a result, RF signals from LNA 615 are routed to LNA 205 and receive circuits 145 matching network 235, matching network 225, balun 130, and matching network 210. Consequently, RF signals are received via antenna 110 and processed by receive circuits 145.
Note that a variety of alternatives to circuit arrangement 600 are possible and contemplated. For example, in some embodiments, LNA 615 may be omitted, while PA 610 is used. As another example, in some embodiments, PA 610 may be omitted, while LNA 615 is used.
As yet another example, in some embodiments, both LNA 615 and PA 610 may be omitted. In this situation, FEM 605 includes switch 620, which serves as a receive/transmit switch for circuit arrangement 600. LNA 205 and PA 215 may be used in such an arrangement, as described above in detail.
Some of the exemplary embodiments described include matching networks and/or harmonic filters. A variety of types and configurations of matching networks and harmonic filters may be used, as persons of ordinary skill in the art will understand. For example, in some embodiments, capacitive (C) or inductive (L) matching networks and/or harmonic filters may be used. As another example, in some embodiments, -resistor-capacitor (RC) or resistor-inductor (RL) matching networks and/or harmonic filters may be used. As another example, in some embodiments, capacitor-inductor (LC) matching networks and/or harmonic filters may be used. As another example, in some embodiments, resistor-capacitor-inductor (RLC) matching networks and/or harmonic filters may be used.
Furthermore, in some embodiments, matching networks and/or harmonic filters may be coupled between two devices or blocks or components (e.g., in a cascade configuration). In some embodiments, rather than between two devices or blocks or components, matching networks and/or harmonic filters may be coupled to two nodes of the same device, block, or component. In some embodiments, matching networks and/or harmonic filters may be coupled in parallel with two or more devices or blocks or components. Other configurations are also possible and contemplated.
The choice of the matching network and harmonic filter type and topology, and the choice of circuit configuration and topology for the circuits and blocks in which matching networks and harmonic filters are included depends on a number of factors. Such factors include design and performance specifications (e.g., impedance levels of various devices, components, etc.; frequencies or frequency ranges of interest), available technology, IC die-area constraints, power consumption, and the like, as persons of ordinary skill in the art will understand.
One aspect of the disclosure relates to circuitry or devices that may be used to implement switch 120 and/or switch 125.
Switch 705 may be implemented using a variety of techniques and devices or circuits, as persons of ordinary skill in the art will understand. For example, in some embodiments, switch 705 may constitute a semiconductor device. As another example, in some embodiments, switch 705 may include more than one transistor, or transistors with different characteristics (e.g., p-type versus n-type, p-channel versus n-channel, etc.).
Note that in other embodiments, switch 710 may constitute a p-channel MOSFET, as desired. In such embodiments, the control signal from controller 135 (not shown) is inverted (compared to when switch 710 constitutes an n-channel MOSFET) so as to properly control switch 710.
Referring to
Bias circuit 720 provides appropriate DC bias for transistor 710. Bias circuit 720 may be implemented in variety of ways, as persons of ordinary skill in the art will understand. For example, in some embodiments, bias circuit 720 may simply include a resistor that couples the drain of transistor 710 to a voltage source (e.g., the supply voltage of IC 105).
Circuit arrangement 1000 represents a more generalized version of circuit arrangement 900 (see
In some embodiments, network 725 may include one or more inductors and one or more capacitors (i.e., an LC network). In some embodiments, network 725 may include one or more capacitors and one or more resistors (i.e., an RC network). In other embodiments, network 725 may include one or more inductors and one or more resistors (i.e., an RL network). In some embodiments, network 725 may include one or more resistors, one or more capacitors, and one or more inductors (i.e., an RLC network).
Given the AC coupling in
One aspect of the disclosure relates to sharing one or more antennas between RF circuits or devices, such as ICs that include RF circuitry (transmit circuits, receiver circuits, or both (transceiver circuits). Conventionally, in order for two ICs to share an antenna, external circuitry or modules such as diplexers are used.
In exemplary embodiments according to the disclosure, internal switches (i.e., integrated within an IC) are used in ICs to allow sharing of one or more antennas, as described below in detail. Using the internal switches provides for reduced size, reduced part-count, reduced cost, and potentially increased performance.
Similarly, IC 105B includes integrated switch 1150, coupled to terminals 1155 and 1160. Terminals 1155 and 1160 constitute an antenna port of IC 105B. Controller 135 in IC 105B controls the operation of switch 1150 in IC 105B (i.e., causes the switch to open and close). Controller 135 in IC 105B controls the operation of (i.e., causes the switch to open and close).
Terminal 1155 of the antenna port of IC 105A is coupled to antenna 110. Similarly, terminal 1160 of the antenna port of IC 105B is coupled to antenna 115. Terminal 1160 of the antenna port of IC 105A is coupled to terminal 1155 of the antenna port of IC 105B.
As noted above, including switches 1150 in IC 105A and IC 105B, respectively, allows IC 105A and IC 105B to share one or more antennas. In the embodiment shown, two antennas, i.e., antenna 110 and antenna 115, are shared between IC 105A and IC 105B. More specifically, in order for IC 105A to use antenna 110 and antenna 115, controller 135 in IC 105A causes switch 1150 in IC 105A to open. Conversely, controller 135 in IC 105B causes switch 1150 in IC 105B to close and couple terminal 1155 of IC 105B to couple to terminal 1160 of IC 105B, in effect short-circuiting (or nearly or substantially short-circuiting in a practical, non-ideal implementation) the two terminals of the antenna port of IC 105B.
As a result, antenna 115 is coupled to terminal 1160 of the antenna port of IC 105A. In effect, antenna 110 is coupled to terminal 1155 of the antenna port of IC 105A, and antenna 115 is coupled to terminal 1160 of the antenna port of IC 105A. Thus, IC 105A (more specifically, RF circuitry 140) can use antenna 110 and antenna 115 to receive or transmit RF signals, as desired.
Conversely, in order for IC 105B to use antenna 110 and antenna 115, controller 135 in IC 105B causes switch 1150 in IC 105B to open. Furthermore, controller 135 in IC 105A causes switch 1150 in IC 105A to close and couple terminal 1155 of IC 105A to couple to terminal 1160 of IC 105A, in effect short-circuiting (or nearly or substantially short-circuiting in a practical, non-ideal implementation) the two terminals of the antenna port of IC 105A.
As a result, antenna 110 is coupled to terminal 1155 of the antenna port of IC 105B. In effect, antenna 110 is coupled to terminal 1155 of the antenna port of IC 105B, and antenna 115 is coupled to terminal 1160 of the antenna port of IC 105B. Thus, IC 105B (more specifically, RF circuitry 140) can use antenna 110 and antenna 115 to receive or transmit RF signals, as desired.
Thus, using the circuitry and techniques described above, IC 105A and IC 105B can share antenna 110 and antenna 115. This scheme of sharing antennas may be extended to more than two ICs and, generally, to N ICs, where N constitutes a positive integer greater than two.
Specifically, circuit arrangement 1250 includes N ICs, labeled IC 105A through IC 105N. Each of IC 105A through IC 105N includes an integrated switch 1150, coupled to terminal 1150 and terminal 1160 of the antenna port of that IC. IC 105A-105N are coupled in a daisy-chain fashion. In other words, terminal 1160 of IC 105A is coupled to terminal 1155 of IC 105B, whereas terminal 1160 of IC 105 is coupled to terminal 1155 of the following IC, and so on. Terminal 1155 of IC 105A is coupled to antenna 110. Terminal 1160 of IC 105N is coupled to antenna 115.
Sharing antennas 110 and 115 among ICs 105A-105N operates in a manner similar to that described above. For instance, in order for IC 105A to use antenna 110 and antenna 115, controller 135 in IC 105A causes switch 1150 of IC 105A to open. Controllers 135 in ICs 105B-105N, however, cause switches 1150 in ICs 105B-105N to close, effectively coupling antenna 115 to terminal 1160 of IC 105A. Thus, IC 105A has antenna 110 and antenna 115 coupled to its antenna port (i.e., terminal 1150 and terminal 1160, respectively). As a result, IC 105A (more specifically, RF circuitry 140) can use antenna 110 and antenna 115 to receive or transmit RF signals, as desired.
As another example, in order for IC 105N to use antenna 110 and antenna 115, controller 135 in IC 105N causes switch 1150 of IC 105N to open. Controllers 135 in the remaining ICs (ICs 105A-105N-1), however, cause switches 1150 in the remaining ICs to close, effectively coupling antenna 110 to terminal 1155 of IC 105N. Consequently, IC 105N has antenna 110 and antenna 115 coupled to its antenna port (i.e., terminal 1150 and terminal 1160, respectively). Thus, IC 105N (more specifically, RF circuitry 140) can use antenna 110 and antenna 115 to receive or transmit RF signals, as desired.
Another aspect of the disclosure relates to sharing a single antenna among multiple ICs.
Unlike
Sharing antenna 110 works in a similar manner as described above in connection with
As a result, ground potential is coupled to terminal 1160 of the antenna port of IC 105A. In effect, antenna 110 is coupled to terminal 1155 of the antenna port of IC 105A, and ground potential is coupled to terminal 1160 of the antenna port of IC 105A. Thus, IC 105A (more specifically, RF circuitry 140) can use antenna 110 and antenna 115 to receive or transmit RF signals, as desired.
Conversely, in order for IC 105B to use antenna 110, controller 135 in IC 105B causes switch 1150 in IC 105B to open. Furthermore, controller 135 in IC 105A causes switch 1150 in IC 105A to close and couple terminal 1155 of IC 105A to couple to terminal 1160 of IC 105A, in effect short-circuiting (or nearly or substantially short-circuiting in a practical, non-ideal implementation) the two terminals of the antenna port of IC 105A.
As a result, antenna 110 is coupled to terminal 1155 of the antenna port of IC 105B. In effect, antenna 110 is coupled to terminal 1155 of the antenna port of IC 105B, and ground potential is coupled to terminal 1160 of the antenna port of IC 105B. Consequently, IC 105B (more specifically, RF circuitry 140) can use antenna 110 and antenna 115 to receive or transmit RF signals, as desired. Thus, using the circuitry and techniques described above, IC 105A and IC 105B can share antenna 110.
This scheme of sharing a single antenna may be extended to more than two ICs and, generally, to N ICs, where N constitutes a positive integer greater than two.
Specifically, circuit arrangement 1350 includes N ICs, labeled IC 105A through IC 105N. Each of IC 105A through IC 105N includes an integrated switch 1150, coupled to terminal 1150 and terminal 1160 of the antenna port of that IC. IC 105A-105N are coupled in a daisy-chain fashion. In other words, terminal 1160 of IC 105A is coupled to terminal 1155 of IC 105B, whereas terminal 1160 of IC 105 is coupled to terminal 1155 of the following IC, and so on. Terminal 1155 of IC 105A is coupled to antenna 110. Terminal 1160 of IC 105N is coupled to ground potential.
Sharing antennas 110 among ICs 105A-105N operates in a manner similar to that described above. For instance, in order for IC 105A to use antenna 110, controller 135 in IC 105A causes switch 1150 of IC 105A to open. Controllers 135 in ICs 105B-105N, however, cause switches 1150 in ICs 105B-105N to close, effectively coupling the ground potential to terminal 1160 of IC 105A. Thus, IC 105A has antenna 110 and the ground potential coupled to its antenna port (i.e., terminal 1150 and terminal 1160, respectively). As a result, IC 105A (more specifically, RF circuitry 140) can use antenna 110 and antenna 115 to receive or transmit RF signals, as desired.
As another example, in order for IC 105N to use antenna 110, controller 135 in IC 105N causes switch 1150 of IC 105N to open. Controllers 135 in the remaining ICs (ICs 105A-105N-1), however, cause switches 1150 in the remaining ICs to close, effectively coupling antenna 110 to terminal 1155 of IC 105N. Consequently, IC 105N has antenna 110 and the ground potential coupled to its antenna port (i.e., terminal 1150 and terminal 1160, respectively). Thus, IC 105N (more specifically, RF circuitry 140) can use antenna 110 and antenna 115 to receive or transmit RF signals, as desired.
Similar to the circuit arrangement in
Similar to the circuit arrangement in
Similar to the circuit arrangement in
Similar to the circuit arrangement in
Another aspect of the disclosure relates to a coordination or communication mechanism among ICs that share one or more antennas. More specifically, as noted above, controller 135 in IC 105 in
To coordinate the opening and closing of switches 1150 by controllers 135 among the ICs that share one or more antennas, several mechanisms may be used.
Controller 135 of IC 105A and controller 135 of IC 105B use a signaling or control or coordination mechanism through link 1610 to facilitate the opening and closing of switch 1150 in IC 105A and switch 1150 in IC 105B so that antenna 110 and antenna 115 are shared between IC 105A and IC 105B.
In some embodiments, link 1610 constitutes a serial communication mechanism, and controller 135 of IC 105A and controller 135 of IC 105B use a serial communication protocol or standard to communicate information and coordinate proper opening and closing of switch 1150 in IC 105A and switch 1150 in IC 105B to facilitate antenna sharing. Without limitation, examples of such serial protocols include I2C, SMBus, SPI, RS-232, etc.
In some embodiments, link 1610 constitutes a parallel communication mechanism, and controller 135 of IC 105A and controller 135 of IC 105B use a parallel communication protocol or standard to communicate information and coordinate proper opening and closing of switch 1150 in IC 105A and switch 1150 in IC 105B to facilitate antenna sharing. In some embodiments, link 1610 constitutes a custom or special-purpose link or handshaking mechanism through which controllers 135 of IC 105A and IC 105B can exchange status and control signals or information in order to and coordinate proper opening and closing of switch 1150 in IC 105A and switch 1150 in IC 105B to facilitate antenna sharing.
In response to the instructions or commands, controller 135 in IC 105A and controller 135 in IC 105B coordinate proper opening and closing of switch 1150 in IC 105A and switch 1150 in IC 105B to facilitate antenna sharing. Furthermore, in some embodiments, through links 1670A-1670B, host 1660 can exchange status information and/or other signaling information (e.g., a request for an IC to use antenna 110 and antenna 115) with controller 135 in IC 105A and controller 135 in IC 105B, respectively, as desired.
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One aspect of the disclosure relates to ICs that can accommodate one or more RF technologies, standards, or protocols, and include antenna control and/or antenna sharing switches. For example, in exemplary embodiments, IC 105 or an apparatus that includes IC 105 (or multiple ICs that share one or more antennas, as described above), may accommodate and operate in accordance with standards such as Wi-Fi, Bluetooth, ZigBee, cellular (2G, 2.5G, 3G, 4G, LTE, etc., including implementations such as GSM, etc.), and the like, as desired. Depending on whether RF signal reception, RF signal transmission, or both, are desired, receive circuits 145, transmit circuits 150, or both, respectively, may be used to accommodate desired RF technologies, standards, or protocols.
Referring to the figures, persons of ordinary skill in the art will note that the various blocks shown might depict mainly the conceptual functions and signal flow. The actual circuit implementation might or might not contain separately identifiable hardware for the various functional blocks and might or might not use the particular circuitry shown. For example, one may combine the functionality of various blocks into one circuit block, as desired. Furthermore, one may realize the functionality of a single block in several circuit blocks, as desired. The choice of circuit implementation depends on various factors, such as particular design and performance specifications for a given implementation. Other modifications and alternative embodiments in addition to those described here will be apparent to persons of ordinary skill in the art. Accordingly, this description teaches those skilled in the art the manner of carrying out the disclosed concepts, and is to be construed as illustrative only. Where applicable, the figures might or might not be drawn to scale, as persons of ordinary skill in the art will understand.
The forms and embodiments shown and described should be taken as illustrative embodiments. Persons skilled in the art may make various changes in the shape, size and arrangement of parts without departing from the scope of the disclosed concepts in this document. For example, persons skilled in the art may substitute equivalent elements for the elements illustrated and described here. Moreover, persons skilled in the art may use certain features of the disclosed concepts independently of the use of other features, without departing from the scope of the disclosed concepts.
This application is a continuation-in-part (CIP) of, and incorporates by reference in its entirety for all purposes, U.S. patent application Ser. No. 14/869,916, filed on Sep. 29, 2015, titled “Radio-Frequency Apparatus with Integrated Antenna Control and Associated Methods,” attorney docket number SILA365.
Number | Date | Country | |
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Parent | 15390434 | Dec 2016 | US |
Child | 16370987 | US |
Number | Date | Country | |
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Parent | 14869916 | Sep 2015 | US |
Child | 15390434 | US |