KR20230154547A - Wake-Up receiver Using Two-step Wake-up Scheme and Operating Method thereof - Google Patents

Abstract

A wake-up receiver using a two-stage wake-up technique and a method of operating the same are disclosed.
According to one aspect of the present disclosure, a first correlator detecting a first wakeup code from a signal received during a first time period; And when the first wake-up code is detected, a wake comprising a second correlator that detects a second wake-up code from the signal received during the first time period and a second time period consecutive to the first time period. Provides an up receiver.

Description

Wake-up receiver using two-step wake-up scheme and operating method thereof}

This disclosure relates to a wake-up receiver using a two-stage wake-up technique and a method of operating the same.

The content described below simply provides background information related to this embodiment and does not constitute prior art.

Wake-up radio technology is attracting attention as a technology to reduce standby power in the wireless communication field. Unlike a typical data receiver (Data RX), a wake-up receiver (WuRX) simply determines the presence or absence of a received wake-up signal, consuming much lower power than a data receiver. Easy to implement. By operating the wake-up receiver instead of the main data receiver in a reception standby state in which no actual communication occurs, standby power is reduced, while maintaining quasi-real-time communication by responding almost immediately to received signals.

Recently, as a technology to reduce the average power consumption of a wake-up receiver, a duty-cycling method that periodically turns the wake-up receiver off and on for a certain period of time has been widely used. At this time, power consumption is lowered depending on the duty-cycling ratio of the wakeup receiver, but it is common for reception sensitivity to deteriorate or wakeup delay time to increase.

At this time, as a way to further reduce power consumption for the same wake-up delay time, a duty-cycling method based on a rotating correlator can be used. This means, as shown in FIG. 1, while the N-bit wakeup code is repeatedly transmitted M times, the wakeup receiver wakes up every (M-1) times the time at which one wakeup code is transmitted. , operates in a linear phase for a time equal to the time when one wakeup code is transmitted, and operates in a rotating phase for a time equal to or shorter than the time when one wakeup code is transmitted. Then it goes to sleep again. When the wakeup receiver receives a wakeup code that is circularly shifted in the linear phase, the wakeup signal is detected by rotating the input code using a correlator in the rotation phase and comparing it with the prearranged wakeup code. can do. During the rotation phase, all remaining blocks of the wake-up receiver except the correlator are usually turned off, so the proportion of power consumed in the rotation phase is very small, resulting in a consumption of 1/(M-1) for M times the wake-up delay time. You can have power.

However, since all blocks except the correlator are turned off during the rotation phase, data loss may occur due to the start-up time of the circuit when moving to the data phase after detecting the wake-up signal. . Therefore, a guard time longer than the startup time is required between the wake-up signal and data. However, there is a problem that the startup time is variable and not easy to predict depending on the implementation method of the wakeup receiver.

The purpose of the present disclosure is to provide a wake-up receiver and a method of operating the same that can minimize performance degradation such as reception sensitivity and wake-up delay time through two-stage detection of signals.

The purpose of the present disclosure is to provide a wake-up receiver and a method of operating the same that lower average power consumption and do not require a guard time between a wake-up signal and data.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the description below.

According to one aspect of the present disclosure, a first correlator detecting a first wakeup code from a signal received during a first time period; And when the first wake-up code is detected, a wake comprising a second correlator that detects a second wake-up code from the signal received during the first time period and a second time period consecutive to the first time period. Provides an up receiver.

According to another aspect of the present disclosure, a process of detecting a first wake-up code from a signal received during a first time interval; and when the first wake-up code is detected, detecting a second wake-up code from a signal received during the first time period and a second time period consecutive to the first time period. Provides a method of operating a wake-up receiver.

According to another aspect of the present disclosure, a first wake-up code is detected from a signal received during a first time period, and when the first wake-up code is detected, the first time period and the first wake-up code are continuous with the first time period. a wake-up receiver that detects a second wake-up code from a signal received during a second time period and generates a wake-up alarm; and a data receiver that wakes up in response to the occurrence of the wake-up notification.

As described above, according to an embodiment of the present disclosure, there is an effect of minimizing performance degradation such as reception sensitivity and wake-up delay time through two-stage detection of signals.

Furthermore, according to an embodiment of the present disclosure, there is an effect of eliminating the guard time between the wake-up signal and data.

The effects of the present disclosure are not limited to the effects mentioned above, and other effects not mentioned may be clearly understood by those skilled in the art from the description below.

Figure 1 is a power consumption timing diagram for explaining a rotational correlator-based duty-cycling method.
Figure 2 is a block diagram schematically showing a wireless terminal according to an embodiment of the present disclosure.
Figure 3 is a power consumption timing diagram for explaining the operation of a wake-up receiver according to an embodiment of the present disclosure.
Figure 4 is an example diagram for explaining the performance of a wake-up receiver according to an embodiment of the present disclosure.
Figure 5 is a configuration diagram schematically showing a correlator of a wakeup receiver according to an embodiment of the present disclosure.
Figure 6 is a power consumption timing diagram for explaining the operation of a wake-up receiver according to another embodiment of the present disclosure.
Figure 7 is a configuration diagram schematically showing a correlator of a wakeup receiver according to another embodiment of the present disclosure.
Figure 8 is a finite state machine diagram to explain the operation of a wake-up receiver according to another embodiment of the present disclosure.

Hereinafter, some embodiments of the present disclosure will be described in detail using exemplary drawings. When adding reference signs to components in each drawing, it should be noted that the same components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present disclosure, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present disclosure, the detailed description will be omitted.

In describing the components of the embodiment according to the present disclosure, symbols such as first, second, i), ii), a), and b) may be used. These codes are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the code. In the specification, when a part is said to 'include' or 'have' a certain element, this means that it does not exclude other elements, but may further include other elements, unless explicitly stated to the contrary. .

The detailed description set forth below in conjunction with the accompanying drawings is intended to describe exemplary embodiments of the present disclosure and is not intended to represent the only embodiments in which the present disclosure may be practiced.

Figure 2 is a block diagram schematically showing a wireless terminal according to an embodiment of the present disclosure.

The wireless terminal 20 according to an embodiment of the present disclosure may include all or part of the wakeup receiver 200 and the data receiver 210. Not all blocks shown in FIG. 2 are essential components, and some blocks included in the wireless terminal 20 may be added, changed, or deleted in other embodiments. That is, Figure 2 exemplarily shows components for the wireless terminal 20 to detect a wake-up signal and wake up the data receiver 210, and the wireless terminal 20 is shown to perform other functions. It should be recognized that it may have more or fewer components or a configuration of different components.

The wakeup receiver 200 can wake up the data receiver 210 based on a two-stage wakeup technique. Specifically, the wake-up receiver 200 includes a first wake-up alarm (WU ₁ ) for waking up at least one internal component and a second wake-up alarm (WU) for waking up the data receiver 210. ₂ ) can occur.

For example, the wake-up receiver 200 may generate a first wake-up alarm (WU ₁ ) when a first wake-up code is detected from a signal received during a first time period. When the first wake-up code is detected, the wake-up receiver 200 detects the second wake-up code from the signal received during the first time period and the second time period consecutive to the first time period and performs the second wake-up An alarm (WU ₂ ) can be generated. At this time, the data receiver 210 may wake up in response to the occurrence of the second wake-up alarm (WU ₂ ).

Hereinafter, the operation of the wakeup receiver according to some embodiments of the present disclosure will be described in detail with reference to FIGS. 3 to 8.

Figure 3 is a power consumption timing diagram for explaining the operation of a wake-up receiver according to an embodiment of the present disclosure.

Referring to FIG. 3, the wakeup receiver 200 according to the first embodiment of the present disclosure may be implemented in an always-on manner. At this time, the second wake-up code (W ₂ ) transmitted to the wireless terminal 20 may have a form in which the first wake-up code (W ₁ ) is repeated multiple times. For example, the second wake-up code (W ₂ ) may be composed of two first wake-up codes (W ₁ ).

Here, the first wakeup code (W ₁ ) may be an N _1- bit code transmitted in a bit period of τ _b . Accordingly, the second wakeup code (W2) may be an N _2- bit code transmitted with a bit period of τ _b . Meanwhile, the following explains that the wake-up codes used in the present disclosure are one-dimensional wake-up codes, but the present disclosure is not limited thereto. For example, according to other embodiments of the present disclosure, a multidimensional wakeup signal may be utilized by utilizing the size of the input signal, the frequency of the input signal, and the length of the input signal.

The operation section of the wakeup receiver 200 according to the first embodiment can be largely divided into an idle phase and a low-FAR phase. The wake-up receiver 200 basically operates in an idle phase and may transition to the Low-FAR phase in response to the occurrence of the first wake-up alarm (WU ₁ ).

In the idle phase, the wake-up receiver 200 may detect the first wake-up code (W ₁ ), which is part of the second wake-up code (W ₂ ), from the received signal. Here, the wakeup receiver 200 may detect the first wakeup code (W ₁ ) using linear correlation. For example, the wake-up receiver 200 compares a series of bits generated from the received signal with the bits of the previously known first wake-up code (W ₁ ) by position, and if the bits equal to or higher than the preset first threshold match, A first wake-up alarm (WU ₁ ) may be generated.

When the first wake-up alarm (WU ₁ ) occurs, the wake-up receiver 200 additionally observes the signal received after transitioning to the Low-FAR phase to determine whether the second wake-up code (W ₂ ) was really input. can be determined. For example, the wakeup receiver 200 may use a second wakeup code that knows in advance at least some of the series of bits generated from the signal received in the idle phase and the series of bits generated from the signal received in the low-FAR phase. The bits of (W ₂ ) are compared by position, and if the bits equal to or greater than a preset second threshold match, a second wake-up alarm (WU ₂ ) may be generated.

Figure 4 is an example diagram for explaining the performance of a wake-up receiver according to an embodiment of the present disclosure.

Quantitative indicators indicating the performance of the wake-up receiver 200 include the miss-detection ratio (MDR), which is the rate of missing a wake-up signal when it is input, and conversely, the rate at which a false alarm sounds when there is no wake-up signal input. There is a false-alarm rate (FAR), which is a rate, and a wake-up delay time depending on the length of the wake-up signal. Typically, MDR < 0.1% and FAR < 1/hour are the reference points for normal wakeup operation.

In addition, the shorter the wake-up delay time, that is, the length of the wake-up signal, the better, but this is in a trade-off relationship with MDR and FAR.

On the other hand, as the threshold used to detect the wake-up code increases, the FAR decreases, but the processing gain due to the wake-up code decreases. Conversely, as the threshold decreases, the FAR decreases but the spreading gain increases.

Therefore, by varying the FAR for wakeup codes of different lengths, equivalent spreading gains can be obtained. Referring to FIG. 4, if a spreading gain of 17dB is obtained at FAR<1/hour for a 4096-bit wakeup code, a spreading gain of 17dB is obtained if FAR<10% is set for a half-length 2048-bit wakeup code. can still be obtained.

Due to this point, the wake-up receiver 200 according to an embodiment of the present disclosure sends the first wake-up code (W ₁ ), which is half the length of the second wake-up code (W ₂ ), in the idle phase to Low- Detection is performed with a lower first threshold compared to the FAR phase. Because of this, FAR increases, but there is no performance degradation because the same level of spreading gain can be obtained as when detecting the second wakeup code (W ₂ ). Conversely, in the low-FAR phase, the second wake-up code (W ₂ ) is detected with a relatively high second threshold, and low FAR at the same level as existing technology can be guaranteed.

Figure 5 is a configuration diagram schematically showing a correlator of a wakeup receiver according to an embodiment of the present disclosure.

Referring to FIG. 5, the wakeup receiver 200 according to an embodiment of the present disclosure may include all or part of the first correlator 510 and the second correlator 520. Not all blocks shown in FIG. 5 are essential components, and in other embodiments, some blocks included in the wakeup receiver 200 may be added, changed, or deleted. That is, Figure 5 exemplarily shows components for the wake-up receiver 200 to detect a wake-up signal and generate a wake-up alarm, and the wake-up receiver 200 is shown to perform other functions. It should be recognized that it may have more or less components or a different configuration of components. For example, the wake-up receiver 200 is a signal processing unit configured to perform pre-processing (e.g., filtering or demodulation, etc.) on a wireless signal received through an antenna, or a wake-up receiver 200 for at least a part of the wake-up receiver 200 during a preset time period. It may further include a duty-cycling unit configured to block supplied power.

While the first correlator 510 operates in both the idle phase and the low-FAR phase, the second correlator 520 may operate only in the low-FAR phase. To this end, the second clock signal CLK2 applied to the second correlator 520 may be activated in response to detection of the first wake-up code W ₁ . Therefore, the wake-up receiver 200 according to an embodiment of the present disclosure operates only the first correlator 510 in the idle phase, thereby saving half the power compared to the existing correlator that detects the second wake-up code (W ₂ ). In the Low-FAR phase, the first correlator 510 and the second correlator 520 can be operated together to consume power at the same level as before. Here, the wake-up receiver 200 operates in the Low-FAR phase only when the first wake-up code (W ₁ ) is detected, so overall, the average power consumption can be about half of the existing power consumption.

The first correlator 510 may detect the first wakeup code from the signal received during the first time period. For example, the first correlator 510 determines the correlation value (Corr1) between a series of bits (hereinafter, first bit string) generated from a signal received during the first time period and the first wakeup code (W ₁ ). It may be configured to generate a first wake-up alarm (WU ₁ ) by comparing whether it is greater than or equal to the 1 threshold (TH1).

Here, the first time interval may be a time interval corresponding to the length of the first wakeup code (W ₁ ). To this end, the first correlator 510 may include a number of first sequential circuits corresponding to the length of the first wakeup code (W ₁ ). For example, the first correlator 510 may include N ₁ first sequential circuits.

Table 1 is a table illustrating bits output by a plurality of sequential circuits included in the first correlator 510 and the second correlator 520 at an arbitrary point in the first time period. Here, information unnecessary to the explanation is omitted by expressing it as -.

Here, B ₁ [N ₁ -1] to B ₁ [0] are bits output by each sequential circuit.

Referring to Table 1, bits generated from signals received at an arbitrary point in time may be sequentially transmitted to a plurality of sequential circuits in synchronization with the first clock signal CLK1.

_The first _correlator 510 uses the bits ( _{W 1} [0:N ₁ -1]) by position, and if bits equal to or greater than the preset first threshold TH1 match, a first wake-up alarm (WU ₁ ) can be generated.

When the first wake-up code (W ₁ ) is detected, the second correlator 520 detects the second wake-up code from the signal received during the first time period and the second time period consecutive to the first time period. You can. Here, the second time section may be a time section after the first wake-up alarm (WU ₁ ) occurs. The maximum length of the second time section may correspond to the length of the first wakeup code (W ₁ ).

For example, the second correlator 520 calculates the correlation value between a series of bits (hereinafter, second bit string) generated from the signal received during the first bit string and the second time interval and the second wakeup code (W ₂ ). It may be configured to generate a second wake-up alarm (WU ₂ ) by comparing whether (Corr2) is greater than or equal to the second threshold (TH2).

The second correlator 520 may sequentially receive at least one bit constituting the first bit string from the first correlator 510 and calculate a correlation value with the first wakeup code (W ₁ ). To this end, the second correlator 520 may include a number of second sequential circuits corresponding to the length of the first wakeup code (W ₁ ). For example, the second correlator 520 may include N ₁ second sequential circuits.

Table 2 is a table illustrating bits output by a plurality of sequential circuits included in the first and second correlators 510 and 520 at arbitrary points in the first and second time sections. Here, information unnecessary to the explanation is omitted by expressing it as -.

Here, B ₁ [N ₁ -1] to B ₁ [0] are bits output by the first sequential circuits, and B ₂ [N ₁ -1] to B ₂ [0] are bits output by the second sequential circuits. am.

Referring to Table 2, in the low-FAR phase, the second sequential circuits may sequentially receive at least one bit constituting the first bit string in synchronization with the second clock signal CLK2.

The second correlator 510 uses bits of the first wake-up code (W ₁ ) that know in advance the bits (B ₂ [N ₁ -1:0]) output by the plurality of second sequential circuits at an arbitrary point in time. The correlation value can be calculated by comparing (W ₁ [N ₁ -1:0]) by location.

Meanwhile, the second correlator 510 calculates the correlation value for the remaining bits that have not been received among the bits constituting the first bit string and a series of bits generated from the signal received during the second time period. You can receive it from (510).

_To this end, the first correlator 510 uses a first wake-up code ₍ A correlation value can be calculated by comparing each position with the bits of W ₁ (W ₁ [N ₁ -1:0]) and transmitted to the second correlator 520.

The second correlator 520 calculates a second correlation value based on the correlation value received from the first correlator 510 and the correlation value calculated by correlating at least a portion of the first bit string with the first wakeup code (W ₁ ). (Corr2) is calculated, and if the second correlation value (Corr2) is greater than or equal to the second threshold (TH2), a second wake-up alarm (WU ₂ ) may be generated.

Meanwhile, as described above, the first threshold TH1 may have a value smaller than the second threshold TH2. Preferably, the first threshold may be set to a value such that the spreading gain in the idle phase achieves the same level as that in the low-FAR phase.

Figure 6 is a power consumption timing diagram for explaining the operation of a wake-up receiver according to another embodiment of the present disclosure.

Referring to FIG. 6, the wakeup receiver 200 according to the second embodiment of the present disclosure may be implemented in a duty-cycling method. At this time, the entire wake-up code transmitted to the wireless terminal 20 may have the form of repeating the second wake-up code (W ₂ ) M times (M is a natural number), and each second wake-up code (W ₂ ) may be composed of two first wakeup codes (W ₁ ).

Here, the first wakeup code (W ₁ ) may be an N _1- bit code transmitted with a bit period of τ _b . Accordingly, the second wayup code (W2) may be an N _2- bit code transmitted with a bit period of τ _b , and the entire wake-up code may be an M·N _2- bit code transmitted with a bit period of τ _b .

The operation period of the wakeup receiver 200 according to the second embodiment of the present disclosure can be largely divided into a linear phase and a rotating phase. In normal times when there is no specially detected signal, the wake-up receiver 200 may periodically wake up from the sleep mode and perform a linear correlator-based duty-cycling operation that operates in a linear phase. Here, the duty-cycle of the wakeup receiver 200 is 1/(M-1), and the period may be (M-1)·N ₂ ·τ _b .

The linear phase can be further divided into a first linear phase and a second linear phase. The wake-up receiver 200 basically operates in the first linear phase, and may transition to the second linear phase when the first wake-up alarm (WU1) occurs.

In the first linear phase, the wake-up receiver 200 may detect the first wake-up code (W ₁ ), which is part of the second wake-up code (W ₂ ), from the received signal. Here, the wakeup receiver 200 may detect the first wakeup code (W ₁ ) using linear correlation. For example, the wake-up receiver 200 compares a series of bits generated from the received signal with the bits of the previously known first wake-up code (W ₁ ) by position, and if the bits equal to or higher than the preset first threshold match, A first wake-up alarm (WU ₁ ) may be generated.

Here, the first threshold of the wakeup receiver 200 is set to have a FAR of less than 10%, which is higher than FAR<1/hour but sufficiently low, so that the second wakeup code ( The same level of diffusion gain as when detecting W ₂ ) can be obtained.

In the second linear phase, the wakeup receiver 200 may additionally observe a signal received after transitioning to the second linear phase to determine whether the second wakeup code (W ₂ ) has actually been input. Here, the wakeup receiver 200 may detect the second wakeup code (W ₂ ) using linear correlation. For example, the wake-up receiver 200 compares a series of bits generated from a signal received during the linear phase with the bits of a previously known second wake-up code (W ₂ ) by position, and selects a bit greater than a preset second threshold. If they match, a second wake-up alarm (WU ₂ ) can be generated.

Meanwhile, when the first wake-up alarm (WU ₁ ) occurs in the linear phase but the second wake-up alarm (WU ₂ ) does not occur, the wake-up receiver 200 may transition to the rotation phase. In the rotation phase, the wakeup receiver 200 may detect the second wakeup code (W ₂ ) using rotation correlation. For example, the wakeup receiver 200 circularly shifts a series of bits generated from a signal received during the linear phase, and circularly shifts the circularly shifted bits and a previously known bit of the second wakeup code (W ₂ ). By comparing the bits by position, if the bits equal to or higher than a preset second threshold match, a second wake-up alarm (WU ₂ ) can be generated.

That is, in normal times when there is no specially detected signal, the wake-up receiver 200 periodically operates in the first linear phase to detect the first wake-up code (W ₁ ), which is half of the second wake-up code (W ₂ ). Perform only At this time, if the first wake-up code (W ₁ ) is detected, it operates in the second linear phase to detect the second wake-up code (W ₂ ), and if the second wake-up code (W ₂ ) is not detected, Additional detection can be performed by operating in a rotation phase.

Meanwhile, the length of the linear phase may correspond to the length of the second wakeup code (W ₂ ). For example, if the first wake-up alarm (WU ₁ ) does not occur until the time operated in the linear phase becomes N ₂ ·τ _b , the wake-up receiver 200 may transition to the sleep mode. On the other hand, if the first wake-up alarm (WU ₁ ) occurs but the second wake-up alarm (WU ₂ ) does not occur until the time operated in the linear phase becomes N ₂ ·τ _b , the wake-up receiver (200 ) can transition to the rotation phase.

The wakeup receiver 200 according to an embodiment of the present disclosure can operate all other circuits except the correlator without turning them off while operating in the rotation phase. That is, the power supplied to all circuits included in the wake-up receiver 200 may not be cut off in the rotation phase. Accordingly, when the second wake-up alarm (WU ₂ ) occurs in the rotation phase and transition to the data phase, data loss due to circuit startup may not occur.

Figure 7 is a configuration diagram schematically showing a correlator of a wakeup receiver according to another embodiment of the present disclosure.

Referring to FIG. 7, the wakeup receiver 200 according to an embodiment of the present disclosure may include all or part of a first correlator 710, a second correlator 720, and a multiplexer 730. Not all blocks shown in FIG. 7 are essential components, and in other embodiments, some blocks included in the wakeup receiver 200 may be added, changed, or deleted.

First correlator 710 may operate in a first linear phase, a second linear phase and a rotational phase, while second correlator 720 may operate in a second linear phase and a rotational phase. To this end, the clock signal CLK1 applied to the first correlator 710 may be activated by giving a multiple of the length corresponding to the second wakeup code, and the second clock applied to the second correlator 720 Signal CLK2 may be activated in response to detection of the first wake-up code W ₁ .

Meanwhile, since the first correlator 710 and the second correlator 720 of FIG. 7 may be the same as or correspond to the first correlator 710 and the second correlator 520 described above in FIG. 5, detailed descriptions are omitted. .

The multiplexer 730 may selectively apply the input (IN) or the output (OUT) of the second correlator 720 to the input of the first correlator 710.

For example, the multiplexer 730 applies the input (IN) to the first correlator ₇₁₀ or applies the output (OUT) of the second correlator 720 to the first correlator ( 710).

Specifically, the multiplexer 730 detects the first wake-up code, but when the sum of the lengths of the first time period and the second time period becomes equal to the length corresponding to the second wake-up code (W ₂ ) If the second wake-up code (W ₂ ) is not detected until then, the output (OUT) of the second correlator 720 may be applied to the first correlator 710. Here, the length of the first time section corresponds to the time during which the wakeup receiver 200 operated in the first linear phase, and the length of the second time section corresponds to the time during which the wakeup receiver 700 operated in the second linear phase. can respond.

When the output (OUT) of the second correlator 720 is applied to the first correlator 710, a series of bits (hereinafter referred to as second bits) generated from the first time interval and the signal received during the second time interval column) may be circularly moved by 1 bit in synchronization with the first clock signal (CLK1) and the second clock signal (CLK2).

Table 3 is a table showing an example in which the second bit string (IN[N ₂ -1:0]) is circularly moved.

At an arbitrary point in the rotation phase, the first correlator 710 calculates the bits ( _{W 1 [} N ₁ -1: 0]) by position, a correlation value is calculated, and this can be transmitted to the second correlator 520.

The second correlator 720 compares the remaining bits of the cyclically shifted second bit string with the previously known bits (W ₁ [N 1 -1:0]) of the first wakeup code (W ₁ [N ₁ -1:0]) by position and performs correlation. A value is calculated, and if the sum of the calculated correlation value and the correlation value received from the first correlator 710 is greater than or equal to the second threshold, a second wake-up alarm (WU ₂ ) may be generated.

That is, the second correlator 720 may generate a second wake-up alarm (WU ₂ ) when the correlation value between the cyclically shifted bits and the second wake-up code (W ₂ ) is greater than or equal to the second threshold. .

Meanwhile, although not shown in FIG. 7, the wake-up receiver 200 may further include a duty-cycling unit configured to block power supplied to at least a portion of the wake-up receiver 200 for a preset time period.

If the duty cycling unit does not detect the first wake _- up code (W ₁ ) until the length of the first time section becomes equal to the length corresponding to the second wake-up code (W 2 ), for example, N ₂ ·τ _b , the power supplied to at least a portion of the wake-up receiver 200 can be cut off to switch the wake-up receiver to a sleep mode. Meanwhile, the duty cycling unit may be configured not to block power supplied to all circuits included in the wake-up receiver 200 while the wake-up receiver 200 operates in the rotation phase.

Figure 8 is a finite state machine diagram for explaining the operation of a wake-up receiver according to another embodiment of the present disclosure.

The wake-up receiver 200 may be equipped with a timer to periodically wake up from the sleep mode and detect a wake-up code. The timer may increase the timer value in synchronization with a predetermined clock signal.

When the duty-cycling operation of the wakeup receiver 200 is activated, the wakeup receiver 200 initializes the timer value to 0 and starts up the circuits necessary for receiving wireless signals and detecting wakeup codes. (S800 and 8210). For example, wakeup receiver 200 may supply power to an RF circuit, first correlator 710 and/or multiplexer 730, etc.

The wakeup receiver 200 may perform linear correlation on the first wakeup code (W ₁ ) (S820). The wake-up receiver 200 may generate a first wake-up alarm (WU ₁ ) when the first wake-up code (W ₁ ) is detected in the received signal.

If the first wake-up alarm (WU ₁ ) does not occur until the time corresponding to the timer value becomes greater than N ₂ ·τ _b +t _SU in S820, the wake-up receiver 200 may enter the sleep mode ( S850). Here, N ₂ is twice the number of bits of the first wake-up code (W ₁ ), τ _b is the bit period of the first wake-up code (W ₁ ), and t _SU is the time required for start-up of the circuit. You can.

On the other hand, if the first wake-up alarm (WU ₁ ) occurs before the time corresponding to the timer value becomes greater than N ₂ ·τ _b +t _SU , the wake-up receiver 200 responds to the second wake-up code (W ₂ ). Linear correlation can be performed (S830). The wake-up receiver 200 may generate a second wake-up alarm (WU ₂ ) when the second wake-up code (W ₂ ) is detected in the received signal.

If the second wake-up alarm (WU ₂ ) does not occur until the time corresponding to the timer value in S830 is greater than N ₂ ·τ _b +t _SU , the wake-up receiver 200 generates the second wake-up code (W ₂ ) can be performed (S840). The wake-up receiver 200 may generate a second wake-up alarm (WU _{2 ) when the cyclically shifted second wake-up code (W 2 )} is detected in the received signal. At this time, the wakeup receiver 200 may keep other circuits, for example, RF circuits, other than the correlator turned on.

If the second wake-up alarm (WU ₂ ) does not occur until the time corresponding to the timer value in S840 is greater than 2·N ₂ ·τ _b +t _SU , the wake-up receiver 200 can enter sleep mode. There is (S850).

In S850, the wakeup receiver 200 may operate in sleep mode until the time corresponding to the timer value becomes greater than (M-1)·N ₂ ·τ _b .

Each component of the device or method according to the present invention may be implemented as hardware or software, or may be implemented as a combination of hardware and software. Additionally, the function of each component may be implemented as software and a microprocessor may be implemented to execute the function of the software corresponding to each component.

Various implementations of the systems and techniques described herein may include digital electronic circuits, integrated circuits, field programmable gate arrays (FPGAs), application specific integrated circuits (ASICs), computer hardware, firmware, software, and/or these. It can be realized through combination. These various implementations may include being implemented as one or more computer programs executable on a programmable system. The programmable system includes at least one programmable processor (which may be a special purpose processor) coupled to receive data and instructions from and transmit data and instructions to a storage system, at least one input device, and at least one output device. or may be a general-purpose processor). Computer programs (also known as programs, software, software applications or code) contain instructions for a programmable processor and are stored on a "computer-readable medium."

Computer-readable recording media include all types of recording devices that store data that can be read by a computer system. These computer-readable recording media are non-volatile or non-transitory such as ROM, CD-ROM, magnetic tape, floppy disk, memory card, hard disk, magneto-optical disk, and storage device. It may be a medium, and may further include a transitory medium such as a data transmission medium. Additionally, the computer-readable recording medium may be distributed in a computer system connected to a network, and the computer-readable code may be stored and executed in a distributed manner.

In the flowchart/timing diagram of this specification, each process is described as being executed sequentially, but this is merely an illustrative explanation of the technical idea of an embodiment of the present disclosure. In other words, a person skilled in the art to which an embodiment of the present disclosure pertains may change the order described in the flowchart/timing diagram and execute one of the processes without departing from the essential characteristics of the embodiment of the present disclosure. Since the above processes can be applied in various modifications and variations by executing them in parallel, the flowchart/timing diagram is not limited to a time series order.

The above description is merely an illustrative explanation of the technical idea of the present embodiment, and those skilled in the art will be able to make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present embodiments are not intended to limit the technical idea of the present embodiment, but rather to explain it, and the scope of the technical idea of the present embodiment is not limited by these examples. The scope of protection of this embodiment should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of this embodiment.

20: wireless terminal
200: wake-up receiver
210: data receiver

Claims (18)

a first correlator that detects a first wakeup code from a signal received during a first time period; and
When the first wake-up code is detected, a second correlator that detects the second wake-up code from the signal received during the first time period and a second time period consecutive to the first time period.
A wake-up receiver comprising: According to paragraph 1,
The second wakeup code is,
A wake-up receiver, characterized in that the first wake-up code is a code that is repeated multiple times. According to paragraph 1,
The clock signal applied to the second correlator is,
A wake-up receiver, characterized in that it is activated in response to detection of the first wake-up code. According to paragraph 1,
The first correlator is,
When the first wake-up code is detected, calculating a correlation value between the first wake-up code and a series of bits generated from a signal received during at least a portion of the first time period and the second time period, Wakeup receiver, characterized in that it is configured to transmit to the second correlator. According to paragraph 1,
The second correlator,
configured to generate a second wake-up alarm by comparing whether a correlation value between a series of bits generated from signals received during the first time period and the second time period and the second wake-up code is greater than or equal to a second threshold. Characterized by a wake-up receiver. According to clause 5,
The first correlator is,
configured to generate a first wake-up alarm by comparing whether a correlation value between a series of bits generated from a signal received during the first time period and the first wake-up code is greater than or equal to a first threshold;
A wake-up receiver, characterized in that the first threshold has a value smaller than the second threshold. According to paragraph 1,
The clock signal applied to the first correlator is,
A wake-up receiver, characterized in that it is activated by giving a multiple of the length corresponding to the second wake-up code. According to paragraph 1,
The first wakeup code is detected, but the second wakeup code is not detected until the sum of the lengths of the first time period and the second time period becomes equal to the length corresponding to the second wakeup code. If not, the bits output by the second correlator are applied to the first correlator in order to circularly shift a series of bits generated from signals received during the first and second time intervals. It further includes a multiplexer,
The second correlator,
A wake-up receiver, characterized in that it is configured to compare whether a correlation value between circularly shifted bits and the second wake-up code is greater than or equal to a second threshold. According to clause 8,
Further comprising a duty-cycling unit configured to block power supplied to at least a portion of the wake-up receiver during a preset time period,
The duty-cycling unit,
The second correlator is configured not to cut off power supplied to all circuits included in the wakeup receiver while comparing whether the correlation value between the circularly shifted bits and the second wakeup code is greater than or equal to a second threshold. As a wake-up receiver. According to paragraph 1,
When the first wake-up code is not detected until the length of the first time section becomes the same as the length corresponding to the second wake-up code, the wake-up receiver is switched to sleep mode. , wake-up receiver. A process of detecting a first wake-up code from a signal received during a first time period; and
When the first wake-up code is detected, a process of detecting a second wake-up code from a signal received during the first time period and a second time period consecutive to the first time period.
A method of operating a wake-up receiver comprising: According to clause 11,
The second wakeup code is,
A method of operating a wake-up receiver, characterized in that the first wake-up code is a code that is repeated multiple times. According to clause 11,
The process of detecting the second wakeup code is,
Characterized in that it includes a process of comparing whether a correlation value between a series of bits generated from signals received in the first time interval and the second time interval and the second wakeup code is greater than or equal to a second threshold. How the up receiver works. According to clause 11,
The process of detecting the second wakeup code is,
calculating a first correlation value between the first wakeup code and a series of bits generated from signals received during at least a portion of the first time period and the second time period;
calculating a second correlation value between the first wakeup code and a series of bits generated from a signal received during at least a portion of the first time interval; and
A process of comparing whether the sum of the first correlation value and the second correlation value is greater than or equal to a second threshold
A method of operating a wake-up receiver, comprising: According to clause 13,
The process of detecting the first wakeup code is,
Comparing whether a correlation value between a series of bits generated from a signal received during the first time period and the first wakeup code is greater than or equal to a first threshold,
A method of operating a wake-up receiver, characterized in that the first threshold has a value smaller than the second threshold. According to clause 11,
The first wakeup code is detected, but the second wakeup code is not detected until the sum of the lengths of the first time period and the second time period becomes equal to the length corresponding to the second wakeup code. If not, circularly shifting a series of bits generated from signals received during the first time period and the second time period; and
A process of comparing whether the correlation value between the circularly shifted bits and the second wakeup code is greater than or equal to a second threshold.
A method of operating a wake-up receiver, further comprising: According to clause 11,
Process of switching to sleep mode when the first wake-up code is not detected until the length of the first time section becomes the same as the length corresponding to the second wake-up code
A method of operating a wake-up receiver, further comprising: Detect a first wake-up code from a signal received during a first time period, and when the first wake-up code is detected, a signal received during the first time period and a second time period consecutive to the first time period. a wake-up receiver that detects a second wake-up code and generates a wake-up alarm; and
A data receiver that wakes up in response to the occurrence of the wake-up alarm
wireless terminal including

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