Front-End Circuit for Simultaneous Transmission and Reception Operation

Abstract

A front end circuit is disclosed. In an embodiment, the circuit includes a first antenna connection and first to third signal paths, each of which include a tunable filter and each of which is connected to the first antenna connection. The circuit further includes at least one phase shifter arranged in at least one of the signal paths between a respective filter and the first antenna connection and a control circuit configured to tune frequency bands of the filters, wherein the filters are operable in a FDD operating mode or a TDD operating mode, and wherein the front-end circuit is simultaneous operable in at least one transmission band and at least one reception band using all three filters and the associated signal paths.

Claims

1-19. (canceled)

20. A front-end circuit comprising: a first antenna connection; a first signal path with a first tunable filter arranged therein and coupled to the first antenna connection; a second signal path with a second tunable filter arranged therein and coupled to the first antenna connection; a third signal path with a third tunable filter arranged therein and coupled to the first antenna connection; at least one phase shifter arranged in at least one of the signal paths between a respective filter and the first antenna connection; and a control circuit configured to tune frequency bands of the filters, wherein the filters are operable in a FDD operating mode or a TDD operating mode, and wherein the front-end circuit is simultaneous operable in at least one transmission band and at least one reception band using all three filters and the associated signal paths.

21. The front-end circuit according to claim 20, wherein the first filter is a Tx filter, and wherein the second and third filters are Rx filters.

22. The front-end circuit according to claim 20, wherein a tuning range of each of the three filters is selected from the group consisting of a range of less than 700 MHz, a range of 700 MHz to 1000 MHz, a range of 1000-1400 MHz, a range of 1400-1700 MHz, a range of 1700-2200 MHz, a range of 2200-2700 MHz, and a range above 2700 MHz.

23. The front-end circuit according to claim 20, further comprising a fourth signal path with a fourth tunable filter arranged therein and coupled to the first antenna connection.

24. The front-end circuit according to claim 23, wherein the fourth filter has a fourth tuning range, and wherein the fourth tuning range only slightly overlaps with each tuning range of each of the other filters.

25. The front-end circuit according to claim 20, wherein the front-end circuit is operable in a duplex operation via an Rx filter and a Tx filter, wherein an Rx frequency band and a Tx frequency band for the duplex operation and a duplex spacing are selectable within tuning ranges, and wherein a further one of the tunable filters is operable in an Rx mode or a Tx mode and in a frequency band which differs from the Tx and Rx frequency bands used for the duplex operation.

26. The front-end circuit according to claim 20, further comprising an antenna tuner arranged in at least one of the signal paths between a respective filter and the first antenna connection.

27. The front-end circuit according to claim 20, further comprising: a second antenna connection; a fifth signal path with a fifth tunable filter arranged therein and coupled to the second antenna connection; a sixth signal path with a sixth tunable filter arranged therein and coupled to the second antenna connection; and a seventh signal path with a seventh tunable filter arranged therein and coupled to the second antenna connection, wherein the first and second antenna connections are connected to outputs of a multiplexer or an antenna switch, and wherein a common input of the multiplexer or the the antenna switch is coupled to an antenna.

28. The front-end circuit according to claim 20, further comprising an RF chip, wherein the RF chip is coupled to the first antenna connection via the signal paths, and wherein a power amplifier or an LNA is arranged between the RF chip and a filter in each signal path.

29. The front-end circuit according to claim 28, further comprising an impedance matching circuit arranged in each signal path between the power amplifier or the LNA and the filter.

30. The front-end circuit according to claim 20, wherein each tunable filter comprises a filter circuit, and wherein each filter circuit comprises capacitances and inductances forming a plurality of LC resonant circuits.

31. The front-end circuit according to claim 20, wherein each tunable filter comprises: a serial signal line having at least four circuit nodes; parallel branches coupled between ground and a respective circuit node; and a high-quality tunable reactance element arranged in each parallel branch, wherein the reactance elements are coupled to one another.

32. The front-end circuit according to claim 31, wherein the reactance elements are coupled to one another via coupling capacitors arranged in the serial signal line between two adjacent circuit nodes in each case.

33. The front-end circuit according to claim 31, wherein end circuit nodes of the at least four circuit nodes are connected to one another via a bridging inductance connected in parallel with the serial signal line, and wherein each reactance element comprises a parallel resonant circuit comprising a parallel circuit of a tunable capacitor and a inductance.

34. The front-end circuit according to claim 33, wherein the tunable capacitors are varactors or a switchable capacitor array comprising MIM or MEMS capacitors.

35. The front-end circuit according to claim 34, wherein each tunable phase shifter and each tunable filter are connected to the control circuit and are tunable by a control signal from the control circuit.

36. A front-end circuit comprising: a first antenna connection and a second antenna connection to each of which a group of three signal paths is connected, each signal path connecting an RF chip to one of the antenna connections, wherein the following is arranged in each signal path: a tunable power amplifier or a tunable LNA; a tunable filter whose input and output impedances are tunable; a phase shifter circuit; the two groups of the three signal paths covering two different frequency ranges selected from the group consisting of a range of less than 700 MHz, a range of 700 MHz to 1000 MHz, a range of 1000-1400 MHz, a range of 1400-1700 MHz, a range of 1700-2200 MHz, a range of 2200-2700 MHz, and a range above 2700 MHz; and each group comprises at least one tunable Tx filter and one tunable Rx filter; and a diplexer connected between an antenna and the first and second antenna connections, wherein the diplexer is configured to separate two selected frequency ranges.

37. The front-end circuit according to claim 36, wherein the diplexer is tunable.

38. The front-end circuit according to claim 36, further comprising a fixed frequency signal path having an acoustic filter, wherein the fixed frequency signal path is connected to at least one of the first and second antenna connections via a permanently set matching network.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0046] The invention is explained in more detail below using exemplary embodiments and the associated figures. The figures are only schematic and are used only for a better understanding of the invention. For the sake of clarity, various components are possibly not illustrated, but their need is known to a person skilled in the art or is clear from the overall context. Elements of the front-end circuit which have not been described in any more detail are presumed to be known, with the result that they do not require any further explanation in terms of their function and structure.

[0047] FIG. 1 shows a simple block diagram of a front-end circuit having three signal paths,

[0048] FIG. 2 shows a filter circuit which can be used to implement a tunable filter,

[0049] FIG. 3 shows a more complex front-end circuit having further components,

[0050] FIG. 4 shows a series of tunable capacitors, as can be used in a filter circuit,

[0051] FIG. 5 shows a switchable capacitor array,

[0052] FIG. 6 shows a front-end circuit having four signal paths,

[0053] FIG. 7 shows a further embodiment of a front-end circuit having four signal paths,

[0054] FIG. 8 shows a front-end circuit having two antennas and four antenna connections,

[0055] FIG. 9 shows a tunable filter having an impedance which is tunable on the input and output sides,

[0056] FIG. 10 shows a front-end circuit having an antenna which manages without an antenna tuner.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

[0057] FIG. 1 shows the block diagram of a simple front-end circuit in which three signal paths SP1 to SP3 are connected to a common antenna connection AT. A tunable filter FT is arranged in each signal path SP. A phase shifter circuit PS1, PS2, PS3 which is tunable is additionally respectively arranged between the tunable filter and the antenna connection. The other ends of the signal paths SP which are opposite the antenna connection AT can be connected to one or more RF chips, for example a transceiver circuit. Each of the tunable filters FT is preferably in the form of a tunable bandpass filter. Each of the filters has a tuning range, the tuning ranges of the three filters illustrated being able to be identical.

[0058] FIG. 2 shows a possible embodiment of a tunable filter circuit FT. A serial signal line SL is connected between a first and a second connection T1, T2. The signal line has four circuit nodes N, to each of which a parallel branch to ground is connected. Each parallel branch comprises a tunable capacitance CT and, in parallel with the latter, an inductance PL. A coupling capacitance CA which is in the form of a coupling capacitor, for example, is provided between two circuit nodes N which are adjacent to one another in the signal line SL.

[0059] Alternatively, a coupling inductance which can serve the same purpose may be provided.

[0060] Coupling capacitances CA, that is to say capacitive elements which couple resonant circuits, may have a capacitance of between 10 fF and 100 pF. Coupling inductances, that is to say inductive elements which couple resonant circuits, may have an inductance of between 1 nH and 300 nH.

[0061] The two terminal circuit nodes N of the signal line SL are connected to a bridging inductance BI which is connected in parallel with the signal line SL. A termination capacitance CA which can be set to be tunable and can be used for impedance matching to the circuit environment is respectively provided beyond the outermost circuit nodes.

[0062] FIG. 3 shows further components of the front-end circuit which can be implemented on a common substrate as a front-end module. As already described, each of the signal paths SP connects a common antenna connection AT to an RF chip TC, for example a transceiver circuit. A preferably tunable amplifier AMP which is in the form of a power amplifier for a transmission path and is in the form of an LNA for a reception path is arranged between the filter FT and the transceiver circuit TC in each signal path SP. A tunable amplifier has the advantage that it may be narrowband and can be matched to the frequency band (passband) respectively set in the filter. This minimizes the losses in the amplifier and reduces interference signals.

[0063] Furthermore, an impedance matching circuit MC may be arranged in the signal path between the amplifier AMP and the tunable filter FT. This impedance matching circuit may be implemented from passive components in a manner known per se. However, it is also possible to dispense with such an impedance matching circuit MC with an optimally matched amplifier and a tunable filter.

[0064] At least one antenna tuner ATU may be arranged between the antenna connection AT and the filter. This tuner is preferably likewise tunable and can be tuned to the respectively set frequency bands.

[0065] FIG. 4 shows an array of four tunable high-quality impedance elements IET which are controlled by a common control unit CE. The arrangement may also comprise a greater number of tunable impedance elements IET. The tunable impedance elements IET have a tunable impedance. They are, for example, in the form of tunable capacitances which are tunable in terms of their capacitance value. The information for tuning can be sent, via an MIPI-RFFE signal (MIPI), to the control unit CE which then accordingly tunes the individual tunable capacitors CT or simply more generally the impedance elements IET. The tunable impedance elements can be implemented in different technologies. The entire arrangement may be implemented in a semiconductor component. The control unit CE generates control for the tunable capacitors from the MIPI-RFFE signal.

[0066] Each of the tunable impedance elements may be a connection of a tunable impedance element to one or more further passive components.

[0067] FIG. 5 shows a possibility of how a tunable capacitance CT can be in the form of a switchable capacitor array. This capacitor array comprises a basic capacitance C0, in parallel with which a first additional capacitance C.sub.1 can be connected with the aid of a first switch SW1. The total capacitance of this parallel circuit corresponds to the sum of the capacitances C.sub.0 and C.sub.1. In an expansion of this switchable array, further capacitors C.sub.n can be connected in parallel by means of further switches SW.sub.n, the capacitances of all individual capacitors connected in parallel being added. A particular capacitance value, and via this capacitance value, the resonant frequency of a resonant circuit, which is part of a tunable filter circuit FC, can be set by varying the capacitance value of the connectable capacitors and by the number of capacitors connected in parallel. The right-hand part of the figure illustrates the circuit symbol for a tunable capacitor CT.

[0068] FIG. 6 shows a front-end circuit which is similar to FIG. 1 but has been expanded by a fourth signal path SP4. This front-end circuit may otherwise be configured as described using FIG. 1. In this case too, a tunable phase shifter circuit PS is respectively arranged between the antenna connection AT and the tunable filter FT and is integrated in the signal path SP. In this case too, the four different tunable filters may have different tuning ranges and may be provided for a common tuning range.

[0069] FIG. 7 shows an expanded front-end circuit using the partial circuit illustrated in FIG. 6. An antenna tuner ATU1 is optionally provided between the tunable filters FT and the antenna connection (not illustrated in the figure). The antenna connection is here the transceiver-side output of a multiplexer MP which is connected to the antenna A via the multiplexer. The multiplexer may be in the form of a diplexer, for example. The diplexer then has a second antenna connection which is remote from the antenna and to which a further optional antenna tuner is or can be connected, further signal paths SP with tunable filters arranged therein being connected or being able to be connected to said antenna tuner. However, the multiplexer may also be in the form of an antenna switch AS which optionally connects the antenna A to one of the two antenna tuners ATU.

[0070] The respective other end of the four signal paths connected to one respective common antenna connection leads to an RF chip, for example a transceiver TC. An amplifier AMP which again may be in the form of a power amplifier or an LNA may also be arranged in each signal path between the tunable filter FT and the transceiver TC. An impedance matching circuit MC may also be provided in each of the signal paths between the amplifier and the tunable filter FT.

[0071] FIG. 7 also provides an optional configuration in which a signal path can be divided between two different signal path elements between the RF chip TC and the tunable filter FT via a band switch BS. Each signal path element comprises its own amplifier and optionally its own impedance matching circuit MC. One of the two signal path elements can be selected via the band switch BS. For example, it is possible to form one of the two signal path elements as a transmission path and to form the other as a reception path. These can together constitute, for example, the transmission and reception path for a TDD mobile radio standard, the band switch BS then simultaneously changing over between transmission operation and reception operation. The changing-over of the band switch BS may be associated with tuning of the tunable filter FT. However, it is also possible to select only the type of amplifier and a corresponding input of the transceiver TC by means of the band switch BS.

[0072] A further antenna tuner may be connected to the second output of the multiplexer MP or of the antenna switch AS and further signal paths may be connected to the further antenna tuner, as described above. This makes it possible to connect a maximum of eight different frequency bands to the antenna at the same time. This is easy when there is a sufficiently large frequency spacing between the tuning ranges of the filters connected to the first antenna tuner or the first antenna connection and the tuning ranges of the filters connected to the second antenna connection, with the result that the respective frequencies can be cleanly separated from one another.

[0073] FIG. 8 shows a front-end circuit configured further for an embodiment having two antennas A1, A2. As illustrated in FIG. 7, each antenna A is connected to a multiplexer MP or to an antenna switch AS which respectively provides two antenna connections at the output. As described in FIG. 3, each of the antenna connections can be connected to three signal paths which are connected to a transceiver TC via a tunable filter, tunable amplifiers and possibly impedance matching circuits MC. As illustrated in FIG. 3, two circuits which can be controlled passively via the multiplexer or actively via the antenna switch are therefore connected to the first antenna A1. In the same manner as in FIG. 3, two front-end circuits which can likewise be controlled via a multiplexer MP or an antenna switch AS are likewise connected to the second antenna A2.

[0074] If a separate frequency range is assigned to each of the four antenna connections illustrated here, together with the signal paths connected thereto, the arrangement which is illustrated in FIG. 8 and can be implemented in a single front-end circuit can be used to cover four different frequency ranges or to receive or transmit transmission and reception signals in these frequency ranges. For example, the frequency range of the complex illustrated at the top of FIG. 8 can be set to a frequency range of 700 to 1000 MHz which corresponds to the tuning range of the three tunable filters. The section which is arranged underneath and is connected to the same antenna Al can have signal paths or tunable filters arranged in the latter tuned to a frequency range of 1700 to 2200 MHz.

[0075] A first complex of three signal lines having tunable filters arranged therein can be connected to the second antenna A2 via an antenna connection AT, which complex covers a tuning range of 1400 to 1700 MHz. The signal paths or the filters arranged therein, which are connected to the second antenna connection, may be tuned to a further frequency range which covers the frequencies of 2300 to 2700 MHz. In this manner, the arrangement can serve all common frequency bands and, since there are two antennas, four power amplifiers (PA) and eight LNAs, can transmit at at least four different frequencies at the same time and can additionally receive in eight different frequency bands.

[0076] FIG. 9 shows a further possible configuration of a tunable filter circuit FT, as can be arranged in each of the tunable signal paths. In addition to the frequency tuning, the circuit also has, on the input and output sides, impedance matching circuits MC which are integrated in a tunable filter circuit as illustrated in FIG. 2, for example. These matching means may be in the form of tunable impedance elements, for example tunable capacitors.

[0077] FIG. 10 shows a further configuration. A diplexer MP which provides virtually two antenna connections at its outputs is connected to an antenna A. A group G1, G2 of three or more signal paths is coupled to each of the two outputs or antenna connections. Each group of signal paths has tunable filters FT, the tuning ranges of the tunable filters in a group being assigned to the same frequency range, but the two groups being assigned to different frequency ranges.

[0078] The two groups or the tuning ranges of the filters inside the two groups are assigned to two different frequency ranges selected from the range of less than 700 MHz, the range from 700 MHz to 1000 MHz, the range from 1000-1400 MHz, the range from 1400-1700 MHz, the range from 1700-2200 MHz, the range from 2200-2700 MHz and the range above 2700 MHz.

[0079] Each tunable filter is designed as illustrated in FIG. 9, for example. Each signal path additionally also has, on the antenna side, a phase shifter circuit PS whose phase angle can be tuned. The diplexer MP is able to separate the two frequency ranges and to allocate corresponding signals within one of the frequency ranges to the corresponding group of signal paths. A phase shifter circuit is arranged between the filter and the antenna connection in the respective signal path, whereas an amplifier AMP which is optionally tunable is arranged in each signal path at the end remote from the antenna. The filter can be optimally matched to the load impedance by means of the tunable filters which, according to FIG. 9, are additionally designed with a tunable input and output impedance. An antenna tuner is not required in this embodiment. The circuit is suitable and usable both for TDD operation and for FDD operation.

[0080] Inside each group of signal paths, at least one signal path, together with the tunable filter, is designed for transmission operation, that is to say as a Tx path, while at least one other signal path in the group G is designed as a reception path, that is to say as an Rx path.

[0081] As illustrated in FIG. 10, the arrangement may also be supplemented with two fixed filter circuits FC1, FC2 each connected to one of the two outputs of the duplexer MP. Each fixed filter circuit has a filter fixedly set to a frequency band and a corresponding amplifier. The filter may also be a duplexer. The filter may be an acoustic filter. A matching network which matches the impedance and phase of the fixed filter circuit to the antenna and the load is connected between the fixed filter circuit FC and the diplexer.

[0082] The additional filter circuits FC may be assigned to the same frequency range as the group of signal paths connected to the same output of the duplexer. A carrier aggregation operating mode is therefore possible, in which bands inside the same frequency range can be simultaneously used for a mobile radio connection.

[0083] A carrier aggregation operating mode with bands which are in different frequency ranges and can transmit at the same time is already possible with the two groups G1, G2 of signal paths which are indeed assigned to different frequency ranges.

[0084] It is also possible to assign the additional filter circuits FC to bands outside the two frequency ranges.

[0085] The invention has been described only using a few exemplary embodiments and is not restricted to the latter. Further components and elements as are conventional for common front-end circuits may be integrated in each of the signal paths illustrated or in each arrangement having the signal paths.

[0086] The tunable filters can be implemented in different technologies. It is also possible to use different technologies inside a single front-end circuit.

[0087] All tunable components of the filter circuit may be implemented in a single component, that is to say in a single semiconductor circuit. However, it is advantageous to divide the components between different components according to their type and/or the Q factor required and to mount them on the front-end module. It is advantageous, for example, to form high-quality inductances as discrete coils and therefore as discrete components.

[0088] The tunable high-quality capacitors may be provided together in one component in which further components of the filter circuits, the antenna tuners or the impedance matching circuits or the multiplexers or antenna switches can be integrated.

[0089] Low-quality components of the proposed front-end circuits may also be in the form of integrated passive components. However, it is also possible to at least partially integrate low-quality passive components in the substrate of the front-end circuit.