RU2704238C1 - High-speed calibration system for a fully digital receiver and an alternating-coding method - Google Patents

Abstract

FIELD: data processing.

SUBSTANCE: invention relates to communication, in particular to a high-speed system for calibrating an entirely digital receiver, and enables a receiver to obtain information on the operating state of the transmitter and to ensure that the receiver achieves optimum characteristics. System comprises a transmitter and a receiver. Transmitter comprises a demultiplexer, a baseband signal processor, a conversion device and a multiplexer. Calibration method includes the following steps: starting the transmitter, wherein the baseband signals are encoded in an alternating manner during the initialization state of the transmitter; inserting the transmitter into a normal operating state and normal encoding of the baseband signals during the normal operating state of the transmitter; wherein the receiver performs digital signal processing on the received signals to obtain baseband demodulated signals and continuously checks whether baseband signals are coded in a conventional manner or with alternation; after performing accurate calibration of the analogue-to-digital converter (ADC) of the receiver, the receiver enters the normal operating state.

EFFECT: invention discloses a high-speed calibration system and a method for calibrating an all-digital receiver based on alternating coding.

10 cl, 6 dwg

Description

Technical field

[0001] The present invention relates to the field of communication and, in particular, to a high-speed calibration system for an all-digital receiver and a method based on alternating coding, which are applicable to a communication system of an all-digital receiver that directly samples with a high-speed analog-to-digital converter (ADC) )

State of the art

[0002] A fully digital receiver converts the carrier frequency signal to a digital signal through an analog-to-digital converter (ADC) at the input of the receiver, that is, at an intermediate frequency, high frequency, or a frequency near the frequency of the receiving antenna. Its subsequent functions (such as down-conversion, filtering and demodulation) are implemented using digital signal processing technology. As a product of a combination of communication technology, computer technology and large-scale digital integrated circuits, the all-digital receiver has the advantages of a simple system design, small size, low cost and excellent versatility, and is increasingly used.

[0003] In accordance with the dependence of the sampling frequency on the bandwidth, the sampling frequency of the ADC should be greater than the doubled working bandwidth of a fully digital receiver. This means that with the increasing bandwidth of communication systems, the sampling frequency of the ADC will increase, and high-speed ADCs will become more and more common in future communication systems. Limited by the speed of electronic devices, high-speed ADCs are usually implemented using alternating sampling with time division by several low-speed (<1 GS / s or lower) ADCs. Therefore, the calibration of the gain and phase of low-speed ADCs to coordinate their work has become an important factor affecting the characteristics of a fully digital receiver.

[0004] When calibrating the ADC of the receiver, stable signals transmitted by the transmitter should be used as a reference. However, the receiver does not know exactly when the remote transmitter will send a steady signal. Therefore, in the past there were two decisions. In the first of them, the receiver detects the received signal, and if the signal amplitude exceeds a threshold value, it is considered that the transmitter has transmitted a stable signal, and this signal is used to calibrate the ADC of the receiver. The second of them developed a mechapnism for calculating the ADC calibration error: when the calibration error exceeds the threshold value, the calibration is considered unsuccessful, and re-calibration is performed until the calibration error is less than the threshold value.

[0005] However, both of the above solutions have disadvantages in calibrating the ADC receiver. In the first decision, when starting (initializing) a remote transmitter, an unstable signal will also be transmitted; the receiver will perceive the unstable signal as stable and use it to calibrate the ADC of the receiver, which will lead to a deterioration in the characteristics of the receiver. In the second solution, it is difficult to calculate the mechanism for calculating the ADC calibration error; There is currently no general way to calculate.

[0006] Summary of the invention

[0007] In order to overcome the disadvantages of the aforementioned prior art, the present invention is directed to a high-speed system and method for calibrating an all-digital receiver based on interleaved coding, which can allow the receiver to know the operating state of the transmitter, to ensure that the analog-to-digital converter (ADC) is calibrated. ) when the receiver receives a stable signal, and ensure that the receiver achieves the best performance.

[0008] The present invention provides a high-speed system for calibrating an all-digital receiver based on alternating coding, comprising a transmitter and a receiver, wherein

[0009] the transmitter is configured to select transmission of a conventional encoded signal or an alternating encoded signal in accordance with the amplitude of the signal;

[0010] the receiver is configured to receive a signal from the transmitter and perform calibration of the analog-to-digital converter (ADC) of the receiver;

[0011] the transmitter comprises a demultiplexer, a baseband signal processor, a conversion device, and a multiplexer; wherein the demultiplexer is connected to two or more than two signal processors of the main frequency band; a demultiplexer and baseband signal processors convert the input serial high-speed data into parallel data and process the baseband signal; a conversion device is configured to convert an output signal of a processor of a signal of a baseband of a transmitter; the multiplexer is configured to convert parallel data into a serial high speed baseband signal.

[0012] In the above-described technical solution, both the transmitter and the receiver include a baseband signal processing circuit based on a digital circuit; however, the conversion of conventional coding and alternating coding is performed by a digital circuit.

[0013] In the above technical solution, the baseband signal transmitted by the transmitter has a fixed format; the receiver synchronizes the fixed format when receiving a baseband signal and processing a baseband signal. In the receiver encoding verification state, the receiver identifies the alternate encoding by means of a synchronization flag with a fixed baseband signal format transmitted by the transmitter.

[0014] In the above-described technical solution, the receiver attempts to synchronize the format of the received signal by sequentially using the reception mode with alternating encoding and the reception mode with conventional encoding and identifies the current encoding mode of the transmitter as conventional encoding mode or alternating encoding mode in accordance with the sign of synchronization of the reception mode format.

[0015] In the above technical solution, there is a conversion device within each of two or more than two signal processors of the baseband of the transmitter; wherein each processor of the baseband signal and the conversion device installed in the baseband signal processor form a data output channel; the conversion device on each channel is turned on and off to switch the baseband signal processing circuitry to output a sequence of conventional encoded signals and a sequence of alternating encoded signals, which allows the multiplexer to output a conventional encoded signal and an alternating encoded signal.

[0016] In the above-described technical solution, the conversion device is activated and turned on by means of software settings.

[0017] In the above technical solution for alternating encoded signals, if the conversion devices on the odd channels are turned on while the conversion devices on the even channels are not turned on, the multiplexer outputs an alternating encoded signal; or if the conversion devices on the even channels are turned on, while the conversion devices on the odd channels are not turned on, the multiplexer outputs an alternating encoded signal. For conventional encoded signals, the conversion devices are not turned on on odd channels, and the conversion devices are not turned on on even channels, then the multiplexer produces a regular encoded signal.

[0018] The present invention further provides a method for high-speed calibration of an all-digital receiver based on interleaved coding, comprising the following steps:

[0019] A: starting the transmitter, while in the initialization state of the transmitter, the amplitude of the signal transmitted by the transmitter is unstable, and the baseband signal has alternating coding;

[0020] B: bringing the transmitter into its normal operating state, while in the normal operating state of the transmitter, the amplitude of the signal transmitted by the transmitter is stable, and the baseband signal changes to accept conventional encoding;

[0021] C: the receiver digitally processes the signal on the received signal to obtain a demodulated baseband signal and continuously checks whether the baseband signal has conventional coding or interleaved coding; and

[0022] D: if the receiver determines that the baseband signal has changed to accept conventional coding, the receiver accurately calibrates the receiver's analog-to-digital converter (ADC) with the signal; upon completion of the accurate calibration of the ADC receiver is completed, the introduction of the receiver in normal operating condition.

[0023] In the above technical solution, the next step is further included between step A and step B: upon completion of the initialization state of the transmitter, the transmitter enters the short standby state, while in the short standby state of the transmitter, the amplitude of the signal transmitted by the transmitter is stable, and the baseband signal still has alternating encoding; and upon completion of the transmitter short standby state, the receiver is returned to its normal operating state.

[0024] In the above technical solution, between the step B and the step C, the following step is further included: when the amplitude of the signal received by the receiver is less than the threshold amplitude, introducing the receiver into a state of loss of the signal of the receiver; when the receiver determines that the amplitude of the received signal is greater than the threshold amplitude, the receiver performs a rough calibration of the ADC of the receiver by means of the received signal; and upon completion of the rough calibration of the ADC receiver, the receiver enters the coding check state.

[0025] Compared with the prior art, the present invention has the following advantages:

[0026] the high speed all-digital receiver calibration system and the interleaved coding method provided by the present invention can enable the receiver to know the transmitter's operating status, ensure that the ADC calibrates the receiver when the receiver receives a stable signal, and ensure that the receiver achieves the best performance; this prevents noise and interference from an unstable signal, avoids recalibration of the ADC receiver and reduces the complexity of calibration algorithms and associated control circuits.

[0027] Furthermore, since both the transmitter and the receiver are based on a digital circuit, it is simple for a digital circuit to convert conventional coding and interlaced coding, which requires not adding hardware but a slight increase in software complexity.

Brief Description of the Drawings

[0028] FIG. 1 is a comparative sequence diagram of a conventional encoded signal and an alternating encoded signal sequence in an embodiment of the present invention, in which the signal sequence length is 8 bits;

[0029] FIG. 2 represents an existing baseband signal processing circuit based on a parallel digital circuit, where the parallel digital circuit has two channels;

[0030] FIG. 3 is a two-channel baseband signal processing circuit capable of providing a sequence of conventional encoded signals or a sequence of alternating encoded signals in an embodiment of the present invention;

[0031] FIG. 4 is an eight-channel baseband signal processing circuit capable of delivering a sequence of conventional encoded signals or a sequence of alternating encoded signals in an embodiment of the present invention;

[0032] FIG. 5 is a 2n-channel baseband signal processing circuit capable of delivering a sequence of conventional encoded signals or a sequence of alternating encoded signals in an embodiment of the present invention; and

[0033] FIG. 6 is an operation state diagram for a high-speed method of calibrating an all-digital interlace-based receiver in an embodiment of the present invention.

[0034] Legend: 101 — transmitter initialization state; 102 - state of short standby of the transmitter; 103 — normal operating state of the transmitter; 104 - state of the signal loss of the receiver; 105 - rough calibration of the ADC receiver; 106 — receiver coding verification status; 107 - accurate calibration of the ADC receiver; 108 — normal operating state of the receiver; 301 - transmitter demultiplexer; 302 — first transmitter of a baseband signal of a transmitter; 303 - the second processor of the signal of the main frequency band of the transmitter; 304 - transmitter multiplexer; 401 - demultiplexer of a two-channel transmitter; 402 — first processor of a baseband signal of a two-channel transmitter; 403 - the second processor signal of the main frequency band of a two-channel transmitter; 404 - multiplexer of a two-channel transmitter; 405 - a first conversion device of a two-channel transmitter; 406 - second conversion device of a two-channel transmitter; 501 - demultiplexer of an eight-channel transmitter; 502 - multiplexer eight-channel transmitter; 503 — a first processor of a signal of a fundamental frequency band of an eight-channel transmitter; 504 is a first conversion device of an eight-channel transmitter; 507 — a third processor of a signal of a fundamental frequency band of an eight-channel transmitter; 508 is a third conversion device eight-channel transmitter; 509 is a fourth processor of a signal of a fundamental frequency band of an eight-channel transmitter; 510 is a fourth conversion device of an eight-channel transmitter; 511 is a fifth processor of a signal of a fundamental frequency band of an eight-channel transmitter; 512 is a fifth conversion device of an eight-channel transmitter; 513 - the sixth processor of the signal of the main frequency band of the eight-channel transmitter; 514 is a sixth conversion device of an eight-channel transmitter; 515 - the seventh processor of the signal of the main frequency band of an eight-channel transmitter; 516 is a seventh eight-channel transmitter conversion device; 517 - the eighth processor of the signal of the main frequency band of an eight-channel transmitter; 518 - the eighth conversion device of the eight-channel transmitter; 601 - demultiplexer 2n-channel transmitter; 602 - multiplexer 2n-channel transmitter; 603 — a first baseband signal processor of a 2n-channel transmitter; 604 is a first 2n-channel transmitter conversion device; 605 - a second processor of the signal of the main frequency band of the 2n-channel transmitter; 606 is a second conversion device 2n-channel transmitter; 607 — a third processor of a signal of a fundamental frequency band of a 2n-channel transmitter; 608 is a third conversion device 2n-channel transmitter; 609 - the fourth processor of the signal of the main frequency band of the 2n-channel transmitter; 610 is a fourth conversion device 2n-channel transmitter; 611 - (2n-1) th processor of a signal of a fundamental frequency band of a 2n-channel transmitter; 612 - (2n-1) e 2n-channel transmitter conversion device; 613 - (2n) th baseband signal processor of a 2n-channel transmitter; and 614 - (2n) e conversion device 2n-channel transmitter.

Detailed Description of Embodiments

[0035] The present invention is further described below with reference to the drawings and specific embodiments in detail.

[0036] An exemplary embodiment of the present invention provides a high-speed, inter-coding, all-digital receiver calibration system based on alternating coding comprising a transmitter and a receiver.

[0037] The transmitter is configured to select transmission of a conventional encoded signal or an alternating encoded signal in accordance with the amplitude of the signal; the receiver is configured to receive a signal from the transmitter and perform calibration of the analog-to-digital converter (ADC) of the receiver; wherein the transmitter comprises a demultiplexer, a baseband signal processor, a conversion device, and a multiplexer; a demultiplexer is connected to two or more than two baseband signal processors; a demultiplexer and baseband signal processors convert the input serial high-speed data into parallel data and process the baseband signal; a conversion device is configured to convert an output signal of a processor of a signal of a baseband of a transmitter; the multiplexer is configured to convert parallel data into a serial high speed baseband signal.

[0038] Both the transmitter and the receiver use a baseband signal processing circuit based on a digital circuit; the conversion of conventional coding and alternating coding is performed by a digital circuit. The baseband signal transmitted by the transmitter has a fixed format; moreover, the receiver synchronizes a fixed format when receiving a signal of the main frequency band and processing the signal of the main frequency band; while being in a state of verification of the coding of the receiver, the receiver identifies the alternating coding by means of a synchronization indicator with a fixed format of the signal of the main frequency band transmitted by the transmitter.

[0039] The receiver attempts to synchronize the format of the received signal, sequentially using the reception mode with alternating coding and the reception mode with conventional coding, and identifies the current encoding mode of the transmitter as conventional encoding or alternating coding in accordance with the sign of synchronization of the format of the reception mode.

[0040] Virtually every conversion device is coupled to one of two or more two signal processors of the transmitter baseband signal; each baseband signal processor and a conversion device connected to the baseband signal processor form a data output channel; the conversion device on each channel is turned on and off to switch the signal processing circuit of the main frequency band to output a sequence of conventional encoded signals and a sequence of alternating encoded signals, which allows the multiplexer to output a conventional encoded signal and an alternating encoded signal.

[0041] In practice for alternating encoded signals, odd-channel converters are turned on, while even-channel converters are not turned on, and the multiplexer provides an alternating encoded signal; or the conversion devices on the even channels are turned on, while the conversion devices on the odd channels are not turned on, and the multiplexer provides an alternating encoded signal; for conventional encoded signals, the conversion devices on the odd channels are not turned on, the conversion devices on the even channels are not turned on, and the multiplexer outputs a regular encoded signal.

[0042] It can be assumed that, in fact, the signal processor of the base frequency band of the odd channel transmitter is only connected to the transmitter conversion device, and the transmitter conversion device is turned on by software settings; likewise, the even-channel transmitter baseband signal processor is only connected to the transmitter conversion device, and the transmitter conversion device is turned on by software settings.

[0043] As can be seen from FIG. 1, to compare a sequence of a conventional encoded signal and a sequence of alternating encoded signals, the figure shows a sequence of conventional encoded signals of 8 bits in length and a sequence of alternating encoded signals of length 8, in which bits T1, T3 T5 and T7 are converted; conversion means that 0 changes to 1 and 1 changes to 0.

[0044] As can be seen from FIG. 2, for a conventional baseband signal processing circuitry based on a parallel digital circuitry, the existing transmitter demultiplexer 301 converts input serial high speed data to two channel low speed parallel data; a first transmitter baseband signal processor 302 and a second transmitter baseband signal processor 303 digitally processes the signals on parallel data; the processed parallel signal is transmitted to the transmitter multiplexer 304 for conversion to a serial high-speed baseband signal.

[0045] As can be seen from FIG. 3, an example embodiment of the invention provides a two-channel parallel digital circuit, a baseband signal processing circuit capable of delivering a sequence of conventional encoded signals or a sequence of alternating encoded signals. In this embodiment, for example, if the conversion devices on the odd channels are turned on, the conversion devices on the even channels are not turned on, then the multiplexer provides an alternating encoded signal; a two-channel transmitter demultiplexer 401 converts input serial high-speed data into two-channel low-speed parallel data; the first dual-channel transmitter conversion device 405 included in the dual-channel first transmitter baseband signal processor 402 is activated by software settings to convert the output of the dual-channel first transmitter baseband signal processor 402. Conversion means that 0 is replaced by 1, and 1 is replaced by 0. The second processor 403 of the baseband signal of the two-channel transmitter also comprises a second two-channel transmitter conversion device 406. The first two-channel transmitter conversion device 405 is turned on, the second two-channel transmitter conversion device 406 is not turned on, and the two-channel transmitter multiplexer 404 provides a signal that is an alternating encoded signal. The first two-channel transmitter conversion device 405 is not turned on, the second two-channel transmitter conversion device 406 is not turned on, and the two-channel transmitter multiplexer 404 provides a signal that is a conventional encoded signal. In the same way, even-channel converters are turned on, odd-channel converters are not turned on, and the multiplexer also provides an alternating encoded signal.

[0046] As can be seen from FIG. 4, an example embodiment of the invention provides an eight-channel parallel digital circuit, a baseband signal processing circuit capable of delivering a sequence of conventional encoded signals or a sequence of alternating encoded signals. In this embodiment, for example, the odd-channel converting devices are turned on, the even-channel converting devices are not turned on, and the multiplexer provides an alternating encoded signal; an eight-channel transmitter demultiplexer 501 converts input serial high-speed data into eight-channel low-speed parallel data; the first eight-channel transmitter conversion device 504, which is part of the first eight-channel transmitter baseband signal processor 503, is activated by software settings, the third eight-channel transmitter conversion device 508 in the third baseband signal processor 507 in the eight-channel transmitter is activated, the fifth transmitter conversion device 512 into a fifth transmitter baseband signal processor 511 in an eight-channel transmitter is activated and a seventh eight-channel transmitter conversion device 516 in a seventh eight-channel transmitter baseband signal processor 515 is activated; the outputs of the first processor 503 of the baseband signal of the eight-channel transmitter, the third processor 507 of the baseband signal of the eight-channel transmitter, the fifth processor 511 of the baseband signal of the eight-channel transmitter and the seventh processor 513 of the baseband signal of the eight-channel transmitter; the outputs of the second processor 505 of the baseband signal of the eight-channel transmitter, the fourth processor 509 of the baseband signal of the eight-channel transmitter, the sixth processor 513 of the baseband signal of the eight-channel transmitter, the eighth processor 517 of the baseband signal of the eight-channel transmitter are not converted. Conversion means that 0 is replaced by 1, and 1 is replaced by 0.

[0047] The first eight-channel transmitter conversion device 504, the third eight-channel transmitter conversion device 508, the fifth eight-channel transmitter conversion device 512 and the seventh eight-channel transmitter conversion device 516 are included, the second eight-channel transmitter conversion device 506, the fourth eight-channel transmitter conversion device 510, the sixth conversion device 514 514 an eight-channel transmitter and an eighth eight-channel transform device 518 of the transmitter is not enabled and the transmitter multiplexer 502 outputs a signal that represents the encoded interleaved signal; in the same way, even-channel converters are turned on, odd-channel converters are not turned on, and the multiplexer also provides an alternating encoded signal.

[0048] The first eight-channel transmitter conversion device 504, the third eight-channel transmitter conversion device 508, the fifth eight-channel transmitter conversion device 512 and the seventh eight-channel transmitter conversion device 516 are not included, the second eight-channel transmitter conversion device 506, the fourth eight-channel transmitter conversion device 510, sixth device 514 eight-channel transmitter conversion and the eighth eight-channel conversion device 518 the other transmitters are not turned on, and the transmitter multiplexer 502 provides a signal that is a regular encoded signal.

[0049] As can be seen from FIG. 5, an example embodiment of the invention provides a 2n-channel parallel digital circuit, a baseband signal processing circuit capable of delivering a sequence of conventional encoded signals or a sequence of alternating encoded signals. In this embodiment, for example, the odd-channel converting devices are turned on, the even-channel converting devices are not turned on, and the multiplexer provides an alternating encoded signal; a 2n-channel transmitter demultiplexer 601 converts input serial high-speed data to 2n-channel low-speed parallel data using software settings. The first 2n-channel transmitter conversion device 604 included with the first 2n-channel transmitter baseband signal processor 603 is activated, the second 2-channel transmitter conversion device 608 of the third 2n-channel transmitter baseband signal processor 607 is activated. Similarly, the odd-channel transmitter conversion devices are activated, and the (2n-1) e 2n-channel transmitter conversion device 612 in the (2n-1) m 2n-channel transmitter baseband signal processor 611 is activated. The output signals of the first processor 603 of the baseband signal of the 2n-channel transmitter, the third processor 607 of the mainband signal of the 2n-channel transmitter, the (2n-1) th processor 611 of the mainband signal of the 2n-channel transmitter on the odd channels are converted; the outputs of the second processor 605 of the baseband signal of the 2n-channel transmitter, the fourth processor 609 of the mainband signal of the 2n-channel transmitter and the 2nth processor 613 of the mainband signal of the 2n-channel transmitter on even channels are not converted. Conversion means that 0 is replaced by 1, and 1 is replaced by 0.

[0050] Converting devices such as the first 2n-channel transmitter conversion device 604, the third 2n-channel transmitter conversion device 608, and the (2n-1) th device of the 2n-channel transmitter on odd channels are included. Converting devices such as the second channel transmitter 2n conversion device 606 606, the fourth channel transmitter 2n conversion device 610 and the 2nth even-channel transmitter conversion device 614 are not included. A 2n-channel transmitter multiplexer 602 provides a signal that is an alternating encoded signal. In the same way, if the conversion devices on the even channels are turned on, the conversion devices on the odd channels are not turned on, the multiplexer also outputs an alternating encoded signal.

[0051] Transmitter conversion devices, such as the first 2n-channel transmitter conversion device 604, the third 2n-channel transmitter conversion device 608, and the (2n-1) -th 2n-channel transmitter conversion device 612, on odd channels are not included, devices transmitter conversions, such as the second 2n-channel transmitter conversion device 606, the fourth 2n-channel transmitter conversion device 610 and the 2nth 2n-channel transmitter conversion device 614, are not included on even channels, and the output signal is a conventional encoded signal.

[0052] As can be seen from FIG. 6, an example embodiment of the present invention further provides a high-speed method for calibrating an all-digital receiver based on interleaved coding, comprising the following steps:

[0053] S1: the transmitter is started at time t0; the state 101 of the initialization of the transmitter takes place in the range between time t0 and time t2; in the transmitter initialization state 101, the amplitude of the signal transmitted by the transmitter is unstable, and the baseband signal has alternating coding;

[0054] S2: initialization of the transmitter is completed at time t2; a short standby state of the transmitter 102 occurs between time t2 and time t3; in the transmitter short standby state 102, the amplitude of the signal transmitted by the transmitter is stable, and the baseband signal still has alternating coding;

[0055] S3: at time t3, when the transmitter short wait state 102 is completed, the transmitter enters the normal operating state of the transmitter 103; in the normal operating state of the transmitter 103, the amplitude of the signal transmitted by the transmitter is stable, and the baseband signal is changed to accept conventional encoding;

[0056] S4: when the amplitude of the signal received by the receiver is less than the amplitude threshold, the receiver is in the state 104 of the loss of the signal of the receiver; when the receiver detects that the amplitude of the received signal is greater than the amplitude threshold at time t1, consider that the transmitter enters the initialization state 101 of the transmitter, and perform a rough calibration 105 of the analog-to-digital converter (ADC) of the receiver by the received signal;

[0057] S5: when the coarse calibration of the ADC of the receiver 105 is completed, the receiver enters the receiver encoding check state 106; in the receiver encoding check state 106, the receiver digitally processes the signal on the received signal to obtain a demodulated baseband signal, and continuously checks whether the baseband signal has conventional coding or interleaved coding; and

[0058] S6: the receiver determines that the baseband signal has changed to accept conventional encoding at time t3, indicating that at that moment the remote transmitter has entered the transmitter's normal state 103 and is transmitting a stable signal; the receiver accurately calibrates the 107 ADCs of the receiver using the signal; upon completion of accurate calibration 107 of the ADC receiver, the receiver enters the normal operating state 108.

[0059] A person skilled in the art can make various modifications and changes to the embodiments of the present invention. If such modifications and changes are within the scope of the claims and equivalents of the present invention, they should also fall within the protection scope of the present invention.

[0060] What is not described in detail in the description should be known to specialists in this field of technology.

Claims (19)

1. A high-speed system for calibrating an all-digital receiver based on alternating coding, characterized in that it contains a transmitter and a receiver, while the transmitter is configured to select transmission of a conventional encoded signal or an alternating encoded signal in accordance with the amplitude of the signal; the receiver is configured to receive a signal from the transmitter and perform calibration of the analog-to-digital converter (ADC) of the receiver; the transmitter comprises a demultiplexer, a baseband signal processor, a conversion device, and a multiplexer; while the demultiplexer is connected to two or more than two processors of the signal of the main frequency band; a demultiplexer and baseband signal processors convert the input serial high-speed data into parallel data and process the baseband signal; a conversion device is configured to convert an output signal of a processor of a signal of a baseband of a transmitter; the multiplexer is configured to convert parallel data into a serial high speed baseband signal. 2. The high-speed calibration system for an all-digital receiver based on alternating coding according to claim 1, characterized in that both the transmitter and the receiver include a baseband signal processing circuit based on a digital circuit; however, the conversion of conventional coding and alternating coding is performed by a digital circuit. 3. The high-speed calibration system for an all-digital receiver based on alternating coding according to claim 2, characterized in that the signal of the main frequency band transmitted by the transmitter has a fixed format; the receiver synchronizes a fixed format when receiving a baseband signal and processing a baseband signal; being in a state of verification of receiver coding, the receiver identifies alternating coding by means of a synchronization flag with a fixed format of the baseband signal transmitted by the transmitter. 4. The high-speed calibration system for an all-digital receiver based on interleaved encoding according to claim 3, characterized in that the receiver tries to synchronize the format of the received signal by sequentially using the reception mode with alternating encoding and the reception mode with conventional encoding, and identifies the current transmitter encoding mode as conventional coding or alternating coding in accordance with the sign of synchronization of the reception mode format. 5. A high-speed calibration system for an all-digital receiver based on alternating coding according to any one of claims 1 to 4, characterized in that there is a conversion device inside each of two or more than two processors of the signal of the main frequency band of the transmitter; each baseband signal processor and a conversion device installed in the baseband signal processor form a data output channel; the conversion device on each channel is turned on and off to switch the baseband signal processing circuitry to output a sequence of conventional encoded signals and a sequence of alternating encoded signals, which allows the multiplexer to output a conventional encoded signal and an alternating encoded signal. 6. The high-speed calibration system for an all-digital receiver based on alternating coding according to claim 5, characterized in that the conversion device is activated and turned on by means of program settings. 7. The high-speed calibration system for an all-digital receiver based on alternating coding according to claim 6, characterized in that: for alternating encoded signals, if the conversion devices on the odd channels are turned on, while the conversion devices on the even channels are not turned on, the multiplexer outputs an alternating encoded signal; or if the conversion devices on the even channels are turned on, while the conversion devices on the odd channels are not turned on, the multiplexer outputs an alternating encoded signal; for conventional encoded signals, the conversion devices on the odd channels are not turned on, the conversion devices on the even channels are not turned on, and the multiplexer outputs a regular encoded signal. 8. The method of high-speed calibration of an all-digital receiver based on alternating coding for the system according to claim 1, characterized in that it contains the following steps: A: start of the transmitter, while in the initialization state of the transmitter, the amplitude of the signal transmitted by the transmitter is unstable, and the signal of the main frequency band has alternating coding; B: introducing the transmitter into its normal operating state, while in the normal operating state of the transmitter, the amplitude of the signal transmitted by the transmitter is stable, and the baseband signal changes to accept conventional coding; C: the receiver performs digital signal processing on the received signal to obtain a demodulated baseband signal and continuously checks whether the baseband signal has conventional coding or interlaced coding; and D: when the receiver determines that the baseband signal has changed to accept conventional coding, the receiver accurately calibrates the receiver's analog-to-digital converter (ADC) through the signal; upon completion of the accurate calibration of the ADC receiver, the receiver is brought back to its normal operating state. 9. The method of high-speed calibration of an all-digital receiver based on alternating coding according to claim 8, characterized in that it further comprises the following step between step A and step B: upon completion of the initialization state of the transmitter, the transmitter is put into a short standby state while a short wait for the transmitter, the amplitude of the signal transmitted by the transmitter is stable, and the baseband signal still has alternating coding; and upon completion of the transmitter short standby state, the transmitter is returned to its normal operating state. 10. The method of high-speed calibration of an all-digital receiver based on alternating coding according to claim 8 or 9, characterized in that it further comprises the following step between step B and step C: when the amplitude of the signal received by the receiver is less than the threshold amplitude, introducing the receiver into receiver signal loss state; when the receiver determines that the amplitude of the received signal is greater than the threshold amplitude, the receiver performs a rough calibration of the ADC of the receiver by means of the received signal; and upon completion of the rough calibration of the ADC receiver, the receiver enters the coding check state.

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