Receiving Apparatus, Transmitting Apparatus, and Signal Processing Method
20230045810 · 2023-02-16
Inventors
Cpc classification
Y02D30/70
GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
International classification
Abstract
A receiving apparatus includes at least two first radio frequency signal processors and a first analog signal processor. The at least two first radio frequency signal processors are coupled to the first analog signal processor using at least one first switch circuit. The first radio frequency signal processor is configured to obtain a radio frequency signal to obtain a first analog signal. The first analog signal processor is configured to obtain a first baseband signal based on the first analog signal.
Claims
1. A receiving apparatus comprising: at least one switch circuit; at least two radio frequency signal processors configured to: obtain a radio frequency signal; and obtain an analog signal based on the radio frequency signal; and an analog signal processor coupled to the at least two radio frequency signal processors using the at least one switch circuit, wherein the analog signal processor is configured to obtain a baseband signal based on the analog signal.
2. The receiving apparatus of claim 1, wherein the at least one switch circuit comprises: a first port; and a second port, wherein the at least two radio frequency signal processors comprise: a first radio frequency signal processor coupled to the first port and configured to obtain a first radio frequency signal; and a second radio frequency signal processor coupled to the second port and configured to obtain a second radio frequency signal, and wherein the first radio frequency signal and the second radio frequency signal fall within different frequency ranges.
3. The receiving apparatus of claim 2, wherein the first port of is configured to be connected to receive the first radio frequency signal, wherein the first radio frequency signal processor is further configured to generate an intermediate-frequency analog signal by performing frequency mixing on the first radio frequency signal, and wherein the analog signal processor is further configured to further generate the baseband signal based on the intermediate-frequency analog signal.
4. The receiving apparatus of claim 2, wherein the second port is configured to be connected to receive the second radio frequency signal, wherein the second radio frequency signal processor is further configured to generate a first amplified analog signal by amplifying the second radio frequency signal, and wherein the analog signal processor is further configured to further generate the baseband signal based on the first amplified analog signal.
5. The receiving apparatus of claim 2, wherein the second radio frequency signal processor comprises: a first low noise amplifier; and a first down-conversion mixer coupled to the first low noise amplifier, wherein the second radio frequency signal processor comprises a second low noise amplifier, and wherein the analog signal processor comprises: a first amplifier; and at least two in-phase and quadrature (I/Q) processing circuits comprising: an I-channel processing circuit comprising: a second down-conversion mixer coupled to the first amplifier; a first variable-gain amplifier coupled to the second down-conversion mixer; a first low-pass filter coupled to the first variable-gain amplifier; and a second amplifier coupled to the first low-pass filter; and a Q-channel processing circuit comprising: a third down-conversion mixer coupled to the first amplifier; a second variable-gain amplifier coupled to the third down-conversion mixer; a second low-pass filter coupled to the second variable-gain amplifier; and a third amplifier coupled to the second low-pass filter.
6. The receiving apparatus of claim 2, further comprising at least one antenna coupled to the first radio frequency signal processor.
7. A transmitting apparatus comprising: at least one switch circuit; an analog signal processor configured to obtain an analog signal based on a baseband signal; and at least two radio frequency signal processors coupled to the analog signal processor using the at least one switch circuit, wherein the at least two radio frequency signal processors are configured to obtain a radio frequency signal based on the analog signal.
8. The transmitting apparatus of claim 7, wherein the at least one switch circuit comprises: a first port; and a second port, wherein the at least two radio frequency signal processors comprise: a first radio frequency signal processor coupled to the first port and configured to generate a first radio frequency signal; and a second radio frequency signal processor coupled to the second port and configured to generate a second radio frequency signal, and wherein the first radio frequency signal and the second radio frequency signal fall within different frequency ranges.
9. The transmitting apparatus of claim 8, wherein the first port is configured to be connected to receive the first radio frequency signal, wherein the analog signal processor is further configured to generate an intermediate-frequency analog signal based on the baseband signal, and wherein the first radio frequency signal processor is further configured to: obtain the intermediate-frequency analog signal; and further generate the first radio frequency signal by performing frequency mixing on the intermediate-frequency analog signal.
10. The transmitting apparatus of claim 8, wherein the second port is configured to be connected to receive the second radio frequency signal, wherein the analog signal processor is further configured to generate an intermediate-frequency analog signal based on the baseband signal, and wherein the second radio frequency signal processor is further configured to: obtain the intermediate-frequency analog signal; and further generate the third radio frequency signal by performing radio frequency power amplification on the intermediate-frequency analog signal.
11. The transmitting apparatus of claim 8, wherein the analog signal processor comprises: a first amplifier; and at least two in-phase and quadrature I/Q processing circuits comprising: an I-channel processing circuit comprising: a first up-conversion mixer coupled to the first amplifier; a first variable-gain amplifier coupled to the first up-conversion mixer; a first low-pass filter coupled to the first variable-gain amplifier; and a second amplifier coupled to the first low-pass filter; and a Q-channel processing circuit comprising: a second up-conversion mixer coupled to the first amplifier; a second variable-gain amplifier coupled to the second up-conversion mixer; a second low-pass filter coupled to the second variable-gain amplifier; and a third amplifier coupled to the second low-pass filter, wherein the first radio frequency signal processor comprises: a first radio frequency power amplifier; and a third up-conversion mixer coupled to the first radio frequency power amplifier, and wherein the second radio frequency signal processor comprises a second radio frequency power amplifier.
12. The transmitting apparatus of claim 8, further comprising at least one antenna coupled to the first radio frequency signal processor.
13. A signal processing method implemented by a transmitting apparatus, wherein the signal processing method comprises: obtaining, by an analog signal processor of the transmitting apparatus, an analog signal based on a baseband signal; and obtaining, a first radio frequency signal processor of the transmitting apparatus, a radio frequency signal based on the analog signal.
14. The signal processing method of claim 13, further comprising: generating, by the analog signal processor, an intermediate-frequency analog signal based on the baseband signal; and; obtaining, by a first radio frequency signal processor of the transmitting apparatus, the intermediate-frequency analog signal; and generating, by the first radio frequency signal processor by performing frequency mixing on the intermediate-frequency analog signal, a second radio frequency signal.
15. The signal processing method of claim 13, further comprising: generating, by the analog signal processor based on the baseband signal, an intermediate-frequency analog signal; obtaining, by a second radio frequency signal processor of the transmitting apparatus, the intermediate-frequency analog signal; and generating, by the second radio frequency signal processor by performing radio frequency power amplification on the intermediate-frequency analog signal, a second radio frequency signal.
16. The signal processing method of claim 15, wherein the first radio frequency signal and the second radio frequency signal fall within different frequency ranges.
17. The receiving apparatus of claim 2, further comprising at least one antenna coupled to the second radio frequency signal processor.
18. The receiving apparatus of claim 2, wherein the first radio frequency signal and the second radio frequency signal fall within a same frequency range.
19. The transmitting apparatus of claim 8, further comprising at least one antenna coupled to the second radio frequency signal processor.
20. The transmitting apparatus of claim 8, wherein the first radio frequency signal and the second radio frequency signal fall within a same frequency range.
Description
BRIEF DESCRIPTION OF DRAWINGS
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DESCRIPTION OF EMBODIMENTS
[0046] The following describes embodiments of this application with reference to the accompanying drawings in embodiments of this application.
[0047] In the specification, claims, and accompanying drawings of this application, the terms “first”, “second”, “third”, “fourth”, and the like are intended to distinguish between different objects but do not indicate a particular order. In addition, the terms “including”, “having”, and any other variants thereof are intended to cover a non-exclusive inclusion. For example, a process, a method, a system, a product, or a device that includes a series of steps or units is not limited to the listed steps or units, but optionally further includes an unlisted step or unit, or optionally further includes another inherent step or unit of the process, the method, the product, or the device.
[0048] “Embodiment” mentioned in this specification means that a particular feature, structure, or characteristic described with reference to the embodiment may be included in at least one embodiment of this application. The phrase shown in various locations in the specification may not necessarily refer to a same embodiment, and is not an independent or optional embodiment exclusive from another embodiment. It is explicitly and implicitly understood by a person skilled in the art that embodiments described in the specification may be combined with another embodiment.
[0049] The terms such as “component”, “module”, and “system” used in this specification are used to indicate computer-related entities, hardware, firmware, combinations of hardware and software, software, or software being executed. For example, a component may be but is not limited to a process that runs on a processor, a processor, an object, an executable file, an execution thread, a program, and/or a computer. As illustrated by using figures, both a computing device and an application that runs on a computing device may be components. One or more components may reside within a process and/or an execution thread, and a component may be located on one computer and/or distributed between two or more computers. In addition, these components may be executed from various computer-readable media that store various data structures. For example, the components may communicate by using a local and/or remote process and based on a signal having one or more data packets (for example, data from two components interacting with another component in a local system and/or a distributed system, and/or across a network, for example, the Internet interacting with another system by using the signal).
[0050] To make the technical solutions described in this application more comprehensible, the following describes this application in detail with reference to the accompanying drawings.
[0051]
[0052] The first radio frequency signal processing module 11 is configured to obtain a radio frequency signal, to obtain a first analog signal.
[0053] The first analog signal processing module 13 is configured to obtain a first baseband signal based on the first analog signal.
[0054] In an example, as shown in
[0055] In an example, the first threshold may be a specific value that is set before delivery of the receiving apparatus 10 described in this application. In an example, the first threshold may be an empirical value (for example, the empirical value may be set to a standard value by default in the field of radio frequency) obtained by a person skilled in the art through continuous experiments in an evolution process of the 2nd generation (2G), the 3rd generation (3G), the 4th generation (4G), or even the 5th generation (5G). For example, the first threshold may be 2.4 GHz. For another example, the first threshold may be 5.8 GHz. Further, in an actual application, the first threshold may be adjusted, and values of the first threshold may be different in different application scenarios.
[0056] It should be noted that, in this embodiment of this application, the at least two first radio frequency signal processing modules may include two first radio frequency signal processing modules (for example, the second radio frequency signal processing module and the third radio frequency signal processing module that are mentioned above), and may alternatively include three first radio frequency signal processing modules. For example, the three first radio frequency signal processing modules include a second radio frequency signal processing module and a third radio frequency signal processing module, and may further include another radio frequency signal processing module other than the second radio frequency signal processing module and the third radio frequency signal processing module. When the at least two first radio frequency signal processing modules include three or more radio frequency signal processing modules, in an example, the three or more radio frequency signal processing modules may receive three or more radio frequency signals within different frequency ranges. In an example, several (for example, two) of the three or more radio frequency signal processing modules may receive radio frequency signals within a same frequency range, another radio frequency signal processing module may receive a radio frequency signal within another frequency range, and the like. This is not more limited herein.
[0057] In an example, as shown in
[0058] In an example, as shown in
[0059] With reference to
[0060] In an example, as shown in
[0061] With reference to a schematic diagram of the structure of the receiving apparatus 10 shown in
[0062] The following describes working processes when the first switch circuit in the receiving apparatus 10 is in different connected states.
[0063] In an example, when the baseband processor 15 learns that the second radio frequency signal processing module obtains the first radio frequency signal from the first antenna (for example, the first antenna is a receive antenna), the baseband processor 15 sets the first port of the at least one first switch circuit to the connected state. In this case, the second radio frequency signal processing module 111 is configured to obtain the first radio frequency signal from the first antenna and generate the first intermediate-frequency analog signal. The first intermediate-frequency analog signal is obtained by performing frequency mixing on the first radio frequency signal. The first analog signal processing module 13 is configured to generate a first baseband analog signal based on the first intermediate-frequency analog signal. The analog-to-digital conversion module 14 is configured to generate a first digital baseband signal. The baseband processor 15 is configured to perform processing based on the first digital baseband signal. A first local oscillator signal processing module 17 is configured to generate a first local oscillator signal. A second local oscillator signal processing module 18 is configured to generate a second local oscillator signal.
[0064] In an example, when the baseband processor 15 learns that the third radio frequency signal processing module obtains the second radio frequency signal from the first antenna (for example, the first antenna is a receive antenna), the baseband processor 15 sets the second port of the at least one first switch circuit to the connected state. In this case, the third radio frequency signal processing module 112 is configured to obtain the second radio frequency signal from the first antenna and generate the first amplified analog signal. The first amplified analog signal is obtained by amplifying the second radio frequency signal. The first analog signal processing module 13 is configured to generate a first analog baseband signal based on the first amplified analog signal. The analog-to-digital conversion module 14 is configured to generate a first digital baseband signal. The baseband processor 15 is configured to perform processing based on the first digital baseband signal. A first local oscillator signal processing module 17 is configured to generate a first local oscillator signal. A second local oscillator signal processing module 18 is configured to generate a second local oscillator signal.
[0065] In an example, a specific structure of the receiving apparatus 10 may be shown in
[0066] A second radio frequency signal processing module 111 may include a first LNA and a first down-conversion mixer. In an actual application, in addition to the first LNA and the first down-conversion mixer, the second radio frequency signal processing module 111 may further include a first bypass circuit.
[0067] A third radio frequency signal processing module 112 may include a second LNA. In an actual application, in addition to the second LNA, the third radio frequency signal processing module 112 may further include a second bypass circuit.
[0068] Further, the bypass circuit is distinguished from a main circuit (for example, the main circuit is a circuit including by the second LNA), and means that, when a function is required, the bypass circuit may be switched to another circuit without affecting normal working of the radio frequency signal processing module.
[0069] A first analog signal processing module 13 may include a first amplifier and at least two first quadrature I/Q processing circuits. A first I-channel processing circuit includes a second down-conversion mixer, a first variable-gain amplifier, a first LPF, and a second amplifier. A first Q-channel processing circuit includes a third down-conversion mixer, a second variable-gain amplifier, a second LPF, and a third amplifier. In an example, the first amplifier and the at least two first quadrature I/Q processing circuits may be of an independent structure. In an example, the first amplifier and the at least two first quadrature I/Q processing circuits may be encapsulated together. This is not further limited in this application.
[0070] An analog-to-digital conversion module 14 may include at least two analog-to-digital converters. For example, the at least two analog-to-digital converters may include a first analog-to-digital converter and a second analog-to-digital converter. The first analog-to-digital converter is connected to the first I-channel processing circuit, and the second analog-to-digital converter is connected to the first Q-channel processing circuit.
[0071] A first local oscillator signal processing module 17 may include a first phase-locked loop (PLL) 1 and a first high-frequency oscillator.
[0072] A second local oscillator signal processing module 18 may include a second PLL 2 and a second high-frequency oscillator.
[0073] In this embodiment of this application, a main function of the PLL is to lock a high-frequency oscillator to a low-frequency and stable low-frequency clock source, to enable stability of a high-frequency oscillation source tends to be consistent with stability of the low-frequency clock source. A working principle of the PLL is as follows. A signal generated by the high-frequency oscillation source is processed through frequency dividing to obtain a signal whose frequency is the same as that of a reference clock source, the signal is compared with a frequency/phase of a reference clock signal, and a comparison result is used as an error control signal to control a frequency/phase of the high-frequency oscillator. Through such feedback control, oscillation of the high-frequency oscillator tends to be stable, to output a stable high-frequency signal. Signals obtained by separately performing frequency tripling and frequency halving on the signal generated by the PLL are used as first-stage and second-stage local oscillator signals.
[0074] In this embodiment of this application, the LNA is an amplifier with a very small noise coefficient. Further, the LNA may be configured to amplify a received radio frequency signal.
[0075] In this embodiment of this application, the first LNA and the second LNA may be amplifiers of a same structure and type. The first LNA works within a first range, and the second LNA works within a second range. Herein, the first range and the second range belong to different frequency ranges.
[0076] In an example, the second radio frequency signal processing module 111 may include the first down-conversion mixer. The third radio frequency signal processing module 112 may include the bypass circuit (for example, the bypass circuit is configured to receive a second radio frequency signal). The first analog signal processing module 13 may include the first amplifier and the at least two first quadrature I/Q processing circuits. The first I-channel processing circuit includes the second down-conversion mixer, the first variable-gain amplifier, the first LPF, and the second amplifier. The first Q-channel processing circuit includes the third down-conversion mixer, the second variable-gain amplifier, the second LPF, and the third amplifier. The analog-to-digital conversion module 14 may include the at least two analog-to-digital converters. The first local oscillator signal processing module 17 may include the first PLL 1 and the first high-frequency oscillator. The second local oscillator signal processing module 18 may include the second PLL 2 and the second high-frequency oscillator. In this implementation, the receiving apparatus 10 may be configured to receive a radio frequency signal whose signal-to-noise ratio meets a specified threshold (for example, the radio frequency signal may be a first radio frequency signal or a second radio frequency signal). Herein, the signal-to-noise ratio is a parameter that describes a proportional relationship between a valid component and a noise component in a signal. Usually, a higher signal-to-noise ratio indicates lower noise. For example, the specified threshold may be 90 decibel (dB). It may be understood that, when the signal-to-noise ratio of the radio frequency signal input to the receiving apparatus 10 is 95 dB, the receiving apparatus 10 may complete receiving the radio frequency signal.
[0077] Based on a schematic diagram of the hardware structure of the transceiver apparatus 10 shown in
[0078] Further, in the foregoing descriptions, the “performing frequency mixing on the obtained first radio frequency signal and a first local oscillator signal, to obtain a first intermediate-frequency analog signal” may mean that an absolute value is taken after the obtained first radio frequency signal is subtracted from the first local oscillator signal, to obtain the first intermediate-frequency analog signal. The “sending the first intermediate-frequency analog signal to the first analog signal processing module 13 to perform orthogonal frequency mixing with a second local oscillator signal, to generate two channels of orthogonal first analog baseband signals” may mean that an absolute value is taken after the first intermediate-frequency analog signal is subtracted from the second local oscillator signal, to obtain the two channels of orthogonal first analog baseband signals. It may be understood that, when the first port of the at least one first switch circuit 12 is in the connected state, the receiving apparatus 10 can receive the first radio frequency signal by using a “two-time frequency conversion” structure (a down-conversion process). Herein, the first radio frequency signal falls within the first range. For example, the first radio frequency signal is a high-frequency signal.
[0079] In an example, when a second port of at least one first switch circuit 12 is in a connected state, the third radio frequency signal processing module 112 obtains a second radio frequency signal (for example, the second radio frequency signal falls within a second range) from a receive antenna 16, amplifies the obtained second radio frequency signal to obtain a first amplified analog signal, and then sends the first amplified analog signal to the first analog signal processing module 13 to perform orthogonal frequency mixing with a second local oscillator signal, to generate two channels of orthogonal first analog baseband signals. Then, the two channels of orthogonal first analog baseband signals are sent to the analog-to-digital conversion module 14, to obtain two channels of orthogonal first digital baseband signals, so that the baseband processor 15 can process the two channels of orthogonal first digital baseband signals.
[0080] Further, in the foregoing descriptions, the “sends the first amplified analog signal to the first analog signal processing module 13 to perform orthogonal frequency mixing with a second local oscillator signal, to generate two channels of orthogonal first analog baseband signals” may mean that an absolute value is taken after the first amplified analog signal is subtracted from the second local oscillator signal, to obtain the two channels of orthogonal first analog baseband signals. It may be understood that, when the second port of the at least one first switch circuit 12 is in the connected state, the receiving apparatus 10 can receive the second radio frequency signal by using a “one-time frequency conversion” structure (namely, a zero-intermediate-frequency structure).
[0081] By implementing this embodiment of this application, because the receiving apparatus uses a reused structure, the second radio frequency signal processing module and the third radio frequency signal processing module can process radio frequency signals within different frequency ranges by being switched by using the first switch circuit, to reduce complexity and costs of the receiving apparatus.
[0082] The receiving apparatus shown in
[0083] Step S102: The first radio frequency signal processing module obtains a radio frequency signal, to obtain a first analog signal.
[0084] Step S104: The first analog signal processing module obtains a first baseband signal based on the first analog signal.
[0085] By implementing this embodiment of this application, the receiving apparatus is switched by using the first switch circuit, and the at least two first radio frequency signal processing modules can process radio frequency signals within different frequency ranges, to reduce complexity and costs of the receiving apparatus.
[0086] In a possible implementation, the at least two radio frequency signal processing modules include a second radio frequency signal processing module. The second radio frequency signal processing module is connected to a first port of the at least one first switch circuit. The first port of the at least one first switch circuit is in a connected state. In this case, an implementation process of the signal processing method may include the following. The second radio frequency signal processing module obtains a first radio frequency signal and generates a first intermediate-frequency analog signal. The first intermediate-frequency analog signal is obtained by performing frequency mixing on the first radio frequency signal. Then, the first analog signal processing module generates the first baseband signal based on the first intermediate-frequency analog signal. By implementing this embodiment of this application, because the second radio frequency signal processing module is connected to the first port of the at least one first switch circuit, when the first port of the at least one first switch circuit is in the connected state, the first radio frequency signal can be processed by using the second radio frequency signal processing module, and the first baseband signal is generated by using the first analog signal processing module. In this implementation, the receiving apparatus can process a high-frequency radio frequency signal by switching the first switch circuit.
[0087] In a possible implementation, the at least two radio frequency signal processing modules include a third radio frequency signal processing module, and the third radio frequency signal processing module is connected to a second port of the at least one first switch circuit. The second port of the at least one first switch circuit is in a connected state. In this case, an implementation process of the signal processing method may include the following. The third radio frequency signal processing module obtains a second radio frequency signal and generates a first amplified analog signal. The first amplified analog signal is obtained by amplifying the second radio frequency signal. Then, the first analog signal processing module generates the first baseband signal based on the first amplified analog signal. By implementing this embodiment of this application, because the third radio frequency signal processing module is connected to the second port of the at least one first switch circuit, when the second port of the at least one first switch circuit is in the connected state, the second radio frequency signal can be processed by using the third radio frequency signal processing module, and the first baseband signal is generated by using the first analog signal processing module. In this implementation, the receiving apparatus can process a low-frequency radio frequency signal by switching the first switch circuit.
[0088]
[0089] The second analog signal processing module 23 is configured to obtain a second analog signal based on a second baseband signal.
[0090] The fourth radio frequency signal processing module 24 is configured to obtain a radio frequency signal based on the second analog signal.
[0091] In an example, as shown in
[0092] In an example, the first threshold may be a specific value that is set before delivery of the transmitting apparatus 20 described in this application. In an example, the first threshold may be an empirical value (for example, the empirical value may be set to a standard value by default in the field of radio frequency) obtained by a person skilled in the art through continuous experiments in an evolution process of 2G, 3G, 4G, or even 5G. For example, the first threshold may be 2.4 GHz. For another example, the first threshold may be 5.8 GHz. Further, in an actual application, the first threshold may be adjusted, and values of the first threshold may be different in different application scenarios.
[0093] It should be noted that, in this embodiment of this application, the at least two fourth radio frequency signal processing modules may include two fourth radio frequency signal processing modules (for example, the fifth radio frequency signal processing module and the sixth radio frequency signal processing module that are mentioned above), and may alternatively include three fourth radio frequency signal processing modules. For example, the three fourth radio frequency signal processing modules include a fifth radio frequency signal processing module and a sixth radio frequency signal processing module, and may further include another radio frequency signal processing module other than the fifth radio frequency signal processing module and the sixth radio frequency signal processing module. When the at least two fourth radio frequency signal processing modules include three or more radio frequency signal processing modules, in an example, the three or more radio frequency signal processing modules may transmit three or more radio frequency signals within different frequency ranges. In an example, several (for example, two) of the three or more radio frequency signal processing modules may transmit radio frequency signals within a same frequency range, another radio frequency signal processing module may transmit a radio frequency signal within another frequency range, and the like. This is not more limited herein.
[0094] In an example, as shown in
[0095] In an example, as shown in
[0096] With reference to
[0097] In an example, as shown in
[0098] With reference to a schematic diagram of the structure of the transmitting apparatus 20 shown in
[0099] The following describes specific working processes when the second switch circuit in the transmitting apparatus 20 is in different connected states.
[0100] In an example, when the baseband processor 25 controls transmission of the third radio frequency signal, the baseband processor 25 sets the first port of the at least one second switch circuit to the connected state. In this case, the baseband processor 25 is configured to generate a second digital baseband signal. The digital-to-analog conversion module 24 is configured to generate a second analog baseband signal. The second analog signal processing module 23 is configured to generate the second intermediate-frequency analog signal based on the second analog baseband signal. The fifth radio frequency signal processing module 211 is configured to obtain the second intermediate-frequency analog signal and generate the third radio frequency signal. The third radio frequency signal is obtained by performing frequency mixing on the second intermediate-frequency analog signal. A first local oscillator signal processing module 17 is configured to generate a first local oscillator signal. A second local oscillator signal processing module 18 is configured to generate a second local oscillator signal.
[0101] In an example, when the baseband processor 25 controls transmission of the third radio frequency signal, the baseband processor 25 enables the second port of the at least one second switch circuit to be in the connected state. In this case, the baseband processor 25 is configured to generate a second digital baseband signal. The digital-to-analog conversion module 24 is configured to generate a second analog baseband signal. The second analog signal processing module 23 is configured to generate the second intermediate-frequency analog signal based on the second analog baseband signal. The sixth radio frequency signal processing module 212 is configured to obtain the second intermediate-frequency analog signal and generate the fourth radio frequency signal. The fourth radio frequency signal is obtained by performing radio frequency power amplification on the second intermediate-frequency analog signal. A first local oscillator signal processing module 17 is configured to generate a first local oscillator signal. A second local oscillator signal processing module 18 is configured to generate a second local oscillator signal.
[0102] In an example, a hardware structure of the transmitting apparatus 20 may be shown in
[0103] A second analog signal processing module 23 includes at least two second quadrature I/Q processing circuits and a fourth amplifier. A second I-channel processing circuit includes a first up-conversion mixer, a third variable-gain amplifier, a third LPF, and a fifth amplifier. A second Q-channel processing circuit includes a second up-conversion mixer, a fourth variable-gain amplifier, a fourth LPF, and a sixth amplifier. In an example, the fourth amplifier and the at least two second quadrature I/Q processing circuits may be of an independent structure. In an example, the fourth amplifier and the at least two second quadrature I/Q processing circuits may be encapsulated together. This is not further limited in this application.
[0104] A fifth radio frequency signal processing module 211 includes a first radio frequency power amplifier (PA) and a third up-conversion mixer. In an actual application, in addition to the first radio frequency power amplifier (PA) and the third up-conversion mixer, the fifth radio frequency signal processing module 211 may further include a third bypass circuit.
[0105] A sixth radio frequency signal processing module 212 includes a second radio frequency power amplifier. In an actual application, in addition to the second radio frequency power amplifier, the sixth radio frequency signal processing module 212 may further include a fourth bypass circuit.
[0106] Further, the bypass circuit is distinguished from a main circuit (for example, the main circuit is a circuit including the second radio frequency power amplifier), and means that, when a function is required, the bypass circuit may be switched to another circuit without affecting normal working of the radio frequency signal processing module.
[0107] A digital-to-analog conversion module 24 may include at least two digital-to-analog converters. For example, the at least two digital-to-analog converters may include a first digital-to-analog converter and a second digital-to-analog converter. The first digital-to-analog converter is connected to the second I-channel processing circuit, and the second digital-to-analog converter is connected to the second Q-channel processing circuit.
[0108] For specific implementations of a first local oscillator signal processing module 17 and a second local oscillator signal processing module 18, refer to the foregoing descriptions. Details are not described herein again.
[0109] In this embodiment of this application, the first radio frequency power amplifier and the second radio frequency power amplifier may be amplifiers of a same structure and type. The first radio frequency power amplifier works within a first range, and the second radio frequency power amplifier works within a second range. Herein, the first range and the second range belong to different frequency ranges.
[0110] In an example, the second analog signal processing module 23 includes at least two second quadrature UQ processing circuits and a fourth amplifier. The fifth radio frequency signal processing module 211 includes a third up-conversion mixer. The sixth radio frequency signal processing module 212 includes a bypass circuit. The digital-to-analog conversion module 24 may include at least two digital-to-analog converters. The first local oscillator signal processing module 17 may include a first PLL 1 and a first high-frequency oscillator. The second local oscillator signal processing module 18 may include a second PLL2 and a second high-frequency oscillator. In this implementation, the transmitting apparatus 20 can be configured to transmit a radio frequency signal whose output power and/or efficiency meets a specified threshold (for example, the radio frequency signal may be a third radio frequency signal or a fourth radio frequency signal).
[0111] Based on a schematic diagram of the specific structure of the transmitting apparatus 20 shown in
[0112] Further, in the foregoing descriptions, that “the two channels of orthogonal second analog baseband signals are processed by the second analog signal processing module 23, to obtain a second intermediate-frequency analog signal” means that the two channels of orthogonal second analog baseband signals and a second local oscillator signal are added, to obtain the second intermediate-frequency analog signal. The “performing frequency mixing on the second intermediate-frequency analog signal and a first local oscillator signal, to obtain a third radio frequency signal” means that the second intermediate-frequency analog signal and the first local oscillator signal are added, to obtain the third radio frequency signal. It may be understood that, when the first port of the at least one second switch circuit is in the connected state, the transmitting apparatus 20 can transmit the third radio frequency signal by using a “two-time frequency conversion” structure (an up-conversion process). Herein, the third radio frequency signal falls within a first range. For example, the third radio frequency signal is a high-frequency signal.
[0113] In an example, when a second port of at least one second switch circuit is in a connected state, a baseband processor 25 generates a second digital baseband signal, and then sends the second digital baseband signal to the digital-to-analog conversion module 24, to obtain two channels of orthogonal second analog baseband signals. Then, the two channels of orthogonal second analog baseband signals are processed by the second analog signal processing module 23, to obtain a second intermediate-frequency analog signal. The sixth radio frequency signal processing module 212 obtains the second intermediate-frequency analog signal, and performs radio frequency power amplification on the second intermediate-frequency analog signal, to obtain a fourth radio frequency signal. Then, the fourth radio frequency signal is transmitted through a second antenna (for example, the second antenna may be a transmit antenna).
[0114] Further, in the foregoing descriptions, that “the two channels of orthogonal second analog baseband signals are processed by the second analog signal processing module 23, to obtain a second intermediate-frequency analog signal” means that the two channels of orthogonal second analog baseband signals and a second local oscillator signal are added, to obtain the second intermediate-frequency analog signal. It may be understood that the transmitting apparatus 20 can transmit the fourth radio frequency signal by using a “one-time frequency conversion” structure (namely, a zero-intermediate-frequency structure).
[0115] By implementing this embodiment of this application, the transmitting apparatus is switched by using the second switch circuit, and the at least two fourth radio frequency signal processing modules can generate radio frequency signals within different frequency ranges, to reduce complexity and costs of the transmitting apparatus.
[0116] The transmitting apparatus shown in
[0117] Step S202: The second analog signal processing module obtains a second analog signal based on a second baseband signal.
[0118] Step S204: The fourth radio frequency signal processing module obtains a radio frequency signal based on the second analog signal.
[0119] By implementing this embodiment of this application, the transmitting apparatus is switched by using the second switch circuit, and the at least two fourth radio frequency signal processing modules can generate radio frequency signals within different frequency ranges, to reduce complexity and costs of the transmitting apparatus.
[0120] In a possible implementation, the at least two fourth radio frequency signal processing modules include a fifth radio frequency signal processing module, and the fifth radio frequency signal processing module is connected to a first port of at least one second switch circuit. The first port of the at least one second switch circuit is in a connected state. In this case, an implementation process of the signal processing method may include the following. The second analog signal processing module generates a second intermediate-frequency analog signal based on the second baseband signal. Then the fifth radio frequency signal processing module obtains the second intermediate-frequency analog signal and generates a third radio frequency signal. The third radio frequency signal is obtained by performing frequency mixing on the second intermediate-frequency analog signal. By implementing this embodiment of this application, because the fifth radio frequency signal processing module is connected to the first port of the at least one second switch circuit, when the first port of the at least one second switch circuit is in the connected state, the third radio frequency signal can be generated by using the fifth radio frequency signal processing module. In this implementation, the transmitting apparatus can transmit a high-frequency radio frequency signal by switching the second switch circuit.
[0121] In a possible implementation, the at least two fourth radio frequency signal processing modules include a sixth radio frequency signal processing module, and the sixth radio frequency signal processing module is connected to a second port of at least one second switch circuit. The second port of the at least one second switch circuit is in a connected state. In this case, an implementation process of the signal processing method may include the following. The second analog signal processing module generates a second intermediate-frequency analog signal based on the second baseband signal. Then the sixth radio frequency signal processing module obtains the second intermediate-frequency analog signal and generates a fourth radio frequency signal. The fourth radio frequency signal is obtained by performing radio frequency power amplification on the second intermediate-frequency analog signal. By implementing this embodiment of this application, because the sixth radio frequency signal processing module is connected to the second port of the at least one second switch circuit, when the second port of the at least one second switch circuit is in the connected state, the fourth radio frequency signal can be generated by using the sixth radio frequency signal processing module. In this implementation, the transmitting apparatus can transmit a low-frequency radio frequency signal by switching the second switch circuit.
[0122]
[0123] In this embodiment of this application, the receiving apparatus 301 and the transmitting apparatus 302 can receive and transmit a radio frequency signal by using a wireless network. An implementation may be any manner well known by a person skilled in the art.
[0124] It may be understood that the receiving apparatus 301 and the transmitting apparatus 302 can be integrated into a same radio frequency circuit. As shown in
[0125] To facilitate better understanding of this application, the following describes several application scenarios to which the technical solutions described in this application are applicable.
[0126] Scenario 1: extended frequency support. The transceiver apparatus 30 can support a communication frequency band from 3 GHz to 5.8 GHz.
[0127] In the conventional technology, a 4G transceiver apparatus (for example, a transceiver) product in a base station is used as an example. Working frequencies of the 4G transceiver apparatus product are distributed in a communication frequency band less than 3 GHz (that is, a communication frequency band greater than 3 GHz is not supported). Subsequently, a License Assisted Access (LAA) 0 technology is introduced. Based on carrier aggregation or dual connectivity, a licensed carrier assists access of an unlicensed carrier, to supplement data service bearing of a Long-Term Evolution (LTE) network, that is, an unlicensed frequency band of 5.8 GHz is used to assist communication in an existing 4G frequency band, to expand communication bandwidth.
[0128] The transceiver apparatus (which includes the receiving apparatus 10 and the transmitting apparatus 20) described in this application can support the communication frequency band from 3 GHz to 5.8 GHz. In an example, an example in which the receiving apparatus 10 receives a first radio frequency signal whose communication frequency is 5.8 GHz is used. When a first port of at least one first switch circuit is in a connected state, a second radio frequency signal processing module obtains the first radio frequency signal whose communication frequency is 5.8 GHz from a first antenna, and performs frequency mixing on the first radio frequency signal and a first local oscillator signal, to obtain a first intermediate-frequency analog signal. Then, the first intermediate-frequency analog signal is sent to a first analog signal processing module to perform orthogonal frequency mixing with a second local oscillator signal, to generate two channels of orthogonal first baseband signals (for example, first analog baseband signals), so that the first radio frequency signal whose communication frequency is 5.8 GHz can be received.
[0129] In an example, an example in which the receiving apparatus 10 receives a second radio frequency signal whose communication frequency is less than or equal to 3 GHz is used. When a second port of at least one first switch circuit is in a connected state, a third radio frequency signal processing module obtains the second radio frequency signal whose communication frequency is less than or equal to 3 GHz from a first antenna, and amplifies the obtained second radio frequency signal, to obtain a first amplified analog signal. Then, the first amplified analog signal is sent to a first analog signal processing module to perform orthogonal frequency mixing with a second local oscillator signal, to generate two channels of orthogonal first baseband signals (for example, first analog baseband signals), so that the second radio frequency signal whose communication frequency is less than or equal to 3 GHz can be received.
[0130] In an example, an example in which the transmitting apparatus 20 transmits a third radio frequency signal whose communication frequency is 5.8 GHz is used. When a first port of at least one second switch circuit is in a connected state, two channels of orthogonal second baseband signals (for example, second analog baseband signals) are processed by a second analog signal processing module, to obtain a second intermediate-frequency analog signal. A fifth radio frequency signal processing module obtains the second intermediate-frequency analog signal, and performs frequency mixing on the second intermediate-frequency analog signal and a first local oscillator signal, to obtain the third radio frequency signal whose communication frequency is 5.8 GHz. Then, the third radio frequency signal is transmitted through a second antenna, so that the third radio frequency signal whose communication frequency is 5.8 GHz can be transmitted.
[0131] In an example, an example in which the transmitting apparatus 20 transmits a fourth radio frequency signal whose communication frequency is less than or equal to 3 GHz is used. When a second port of at least one second switch circuit is in a connected state, two channels of orthogonal second baseband signals (for example, second analog baseband signals) are processed by a second analog signal processing module, to obtain a second intermediate-frequency analog signal. A sixth radio frequency signal processing module obtains the second intermediate-frequency analog signal, and performs radio frequency power amplification on the second intermediate-frequency analog signal, to obtain the fourth radio frequency signal whose communication frequency is less than or equal to 3 GHz. Then, the fourth radio frequency signal is transmitted through a second antenna, so that the fourth radio frequency signal whose communication frequency is less than or equal to 3 GHz can be transmitted.
[0132] Scenario 2: use of both a millimeter wave band and an existing 4G communication frequency band
[0133] In this embodiment of this application, when the transceiver apparatus works in a communication frequency band less than 6 GHz, for example, receives a radio frequency signal whose communication frequency is less than 6 GHz, a first analog signal processing module (which is equivalent to a zero-intermediate-frequency receiving architecture in the conventional technology) is used for implementation. For another example, when the transceiver apparatus transmits a radio frequency signal whose communication frequency is less than 6 GHz, a second analog signal processing module (which is equivalent to a zero-intermediate-frequency transmitting architecture in the conventional technology) is used for implementation. When the transceiver apparatus works in the millimeter wave band, for example, receives a radio frequency signal in the millimeter wave band, at least two first radio frequency signal processing modules and a first analog signal processing module (namely, a “two-time” down-conversion structure) are used for implementation. For another example, when the transceiver apparatus transmits a radio frequency signal in the millimeter wave band, at least two fourth radio frequency signal processing modules and a second analog signal processing module (namely, a “two-time” up-conversion structure) are used for implementation.
[0134] It may be understood that, the transceiver apparatus provided in this application can reuse a 4G architecture in a communication frequency band less than 6 GHz.
[0135] Scenario 3: support of a millimeter wave communication frequency band and support of both 15 GHz and 60 GHz
[0136] In the conventional technology, to enable a zero-intermediate-frequency transceiver architecture or a superheterodyne transceiver apparatus with two-time frequency conversion to support both a communication frequency band with a first frequency and a communication frequency band with a second frequency, where a difference between the first frequency and the second frequency is greater than a specified target threshold, for example, the first frequency is 15 GHz, and the second frequency is 60 GHz, it needs to be ensured that a frequency of a local oscillator signal is between 15 GHz and 60 GHz. The bandwidth is very wide, resulting in undoubtedly increasing design difficulty.
[0137] According to the transceiver apparatus described in this application, when the transceiver apparatus works in a communication frequency band of 15 GHz, for example, receives a radio frequency signal whose communication frequency is 15 GHz, a first analog signal processing module (which is equivalent to a zero-intermediate-frequency receiving architecture in the conventional technology) is used for implementation. For another example, when the transceiver apparatus transmits a radio frequency signal whose communication frequency is 15 GHz, a second analog signal processing module (which is equivalent to a zero-intermediate-frequency transmitting architecture in the conventional technology) is used for implementation. When the transceiver apparatus works in a communication frequency band of 60 GHz, for example, receives a radio frequency signal whose communication frequency is 60 GHz, at least two first radio frequency signal processing modules and a first analog signal processing module (namely, a “two-time” down-conversion structure) are used for implementation. For another example, when the transceiver apparatus transmits a radio frequency signal whose communication frequency is 60 GHz, at least two fourth radio frequency signal processing modules and a second analog signal processing module (namely, a “two-time” up-conversion structure) are used for implementation. In an entire implementation process, a narrowband frequency source can be used to provide a local oscillator signal, to reduce design difficulty.
[0138] In conclusion, because the transceiver apparatus provided in this application uses a reused structure, the transceiver apparatus can receive and transmit radio frequency signals with different communication frequencies by being switched by using a switch.
[0139] An embodiment of the present disclosure further provides a computer-readable storage medium. The computer-readable storage medium stores instructions. When the instructions are run on a baseband processor, the baseband processor is enabled to perform one or more steps in the method described in any one of the foregoing embodiments. When being implemented in a form of a software functional unit and sold or used as an independent product, the modules in the foregoing apparatus may be stored in the computer-readable storage medium. Based on such an understanding, the technical solutions of this application essentially, or a part contributing to the conventional technology, or all or some of the technical solutions may be implemented in the form of a computer software product. The computer software product is stored in a computer-readable storage medium.
[0140] The foregoing computer-readable storage medium may be an internal storage unit of a device described in the foregoing embodiment, for example, a hard disk or a memory. The foregoing computer-readable storage medium may be alternatively an external storage device of the foregoing device, for example, a plug-connected hard disk, a smart media card (SMC), a secure digital (SD) card, or a flash card. Further, the foregoing computer-readable storage medium may further include both the internal storage unit and the external storage device of the foregoing device. The foregoing computer-readable storage medium is configured to store a computer program and other program and data that are needed by the foregoing device. The foregoing computer-readable storage medium may be further configured to temporarily store data that has been output or is to be output.
[0141] A person of ordinary skill in the art may understand that all or some of the processes of the methods in the foregoing embodiments may be implemented by a computer program instructing related hardware. The computer program may be stored in a computer-readable storage medium. When the program is executed, the processes of the foregoing method embodiments can be performed. The foregoing storage medium includes various media that can store program code, such as a read-only memory (ROM), a random-access method (RAM), a magnetic disk, and an optical disc.
[0142] The steps of the method in embodiments of this application may be adjusted in sequence, combined, or deleted based on an actual requirement.
[0143] The modules in the apparatus in embodiments of this application may be combined, divided, or deleted based on an actual requirement.
[0144] It may be understood that a person of ordinary skill in the art may be aware that, in combination with the examples described in embodiments disclosed in this application, units and algorithm steps may be implemented by electronic hardware or a combination of computer software and electronic hardware. Whether these functions are performed by hardware or software depends on particular applications and design constraint conditions of the technical solutions. A person skilled in the art may use different methods to implement the described functions for each particular application, but it should not be considered that the implementation goes beyond the scope of this application.
[0145] A person skilled in the art can understand that functions described with reference to various illustrative logical blocks, modules, and algorithm steps disclosed in embodiments of this application may be implemented by hardware, software, firmware, or any combination thereof. If implemented by software, the functions described with reference to the illustrative logical blocks, modules, and steps may be stored in or transmitted over a computer-readable medium as one or more instructions or code and executed by a hardware-based processing unit. The computer-readable medium may include a computer-readable storage medium, which corresponds to a tangible medium, for example, a data storage medium, or a communication medium that include any medium that facilitates transmission of a computer program from one place to another place (for example, according to a communications protocol). In this manner, the computer-readable medium may generally correspond to (1) a non-transitory tangible computer-readable storage medium or (2) a communication medium, for example, a signal or a carrier. The data storage medium may be any usable medium that can be accessed by one or more computers or one or more processors to retrieve instructions, code, and/or data structures for implementing the technologies described in this application. The computer software product may include a computer-readable medium.
[0146] It may be clearly understood by a person skilled in the art that, for the purpose of convenient and brief description, for a detailed working process of the foregoing systems, apparatuses, and units, refer to a corresponding process in the foregoing method embodiments. Details are not described herein again.
[0147] In the several embodiments provided in this application, it should be understood that the disclosed systems, apparatuses, and methods may be implemented in other manners. For example, the described apparatus embodiment is merely an example. For example, the division into the units is merely logical function division and may be other division in actual implementation. For example, a plurality of units or components may be combined or integrated into another system, or some features may be ignored or not performed. In addition, the displayed or discussed mutual couplings or direct couplings or communication connections may be implemented through some interfaces. The indirect couplings or communication connections between the apparatuses or units may be implemented in electrical, mechanical, or other forms.
[0148] The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located at one position, or may be distributed on a plurality of network units. Some or all of the units may be selected based on actual requirements to achieve the objectives of the solutions of embodiments.
[0149] In addition, functional units in embodiments of this application may be integrated into one processing unit, each of the units may exist alone physically, or two or more units may be integrated into one unit.
[0150] When the functions are implemented in a form of a software functional unit and sold or used as an independent product, the functions may be stored in a computer-readable storage medium. Based on such an understanding, the technical solutions of this application essentially, or a part contributing to the conventional technology, or some of the technical solutions may be implemented in a form of a software product. The computer software product is stored in a storage medium, and includes a plurality of instructions for instructing a computer device (which may be a personal computer, a server, or a network device) to perform all or some of the steps of the methods described in embodiments of this application. The foregoing storage medium includes any medium that can store program code, for example, a Universal Serial Bus (USB) flash drive, a removable hard disk, a ROM, a RAM, a magnetic disk, or an optical disc.
[0151] The foregoing descriptions are merely implementations of this application, but are not intended to limit the protection scope of this application. Any variation or replacement readily figured out by a person skilled in the art within the technical scope disclosed in this application shall fall within the protection scope of this application. Therefore, the protection scope of this application shall be subject to the protection scope of the claims.