JP2000078123A - Method and device for correcting frame synchronism - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the frame signal followup ability of reception equipment with respect to the frame signal of transmission equipment and to hold the synchronism between the frame signals of transmission equipment and reception equipment by performing correcting processing for the unit of one frame. SOLUTION: Corresponding to an operating mode 313, a selector 314 switches a timing difference 312 to an output (a) or output (b). The timing difference at the time of output (a) is defined as an initial timing difference value 315 and the timing difference at the time of output (b) is defined as all the timing differences 316 per N frames by adding a timing difference 317 delayed for N frames by the timing difference 312 and flip-flop 318. A correction value calculating part 319 calculates a correction value 320 per frame from the initial timing difference value 315 per N frames or all the timing differences 316. A frame signal correcting part 321 performs the generating and correcting operation of frame signals by the setting of reference clock 302 and correction value 320.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frame synchronization correction device, and more particularly, to a frame synchronization correction device in a communication device such as a portable telephone.

[0002]

2. Description of the Related Art With respect to a conventional frame synchronization correction device,
The operation will be described with reference to the block diagram of FIG. 11 and the timing chart of FIG. In a conventional frame synchronization correction device, a known pattern of a received signal (101) such as a control signal that can be received in a fixed frame cycle (usually called a synchronization word or a unique word; hereinafter, referred to as a UW pattern: a unique word pattern). Is detected, and the value of the reference timer (104) operated by the reference clock (102) is latched by the UW pattern detection pulse (105). By this value (108), UW
Calculate the time when the pattern was received. Then, the time (t
The difference between the value at -1) and the value at time (t) is calculated, and a histogram of the UW pattern reception time is calculated for each UW pattern detection (109), and the reference frame signal of the transmitting device and the reference frame signal of the receiving device are calculated. The integrated timing difference is output (11
0)

[0003] By setting a timing difference allowable value (threshold) (113) to the value of this histogram, the timing correction value detecting unit (111) detects when the timing correction value falls below a negative timing allowable value (reception). When the reference frame signal of the device is shifted backward from the reference frame signal of the transmission device), the reference frame signal of the reception device is corrected forward (112), and when the reference frame signal exceeds the plus timing tolerance (for the reception device). If the reference frame signal is shifted forward from the reference frame signal of the transmitting device), the reference frame signal of the receiving device is corrected backward (112). Actually, when correcting forward, set the initial value of the reference timer to +1.
However, when correcting backward, the initial value of the reference timer is set to −1, and the count value of the reference timer (the frame length of the receiving device) is increased or decreased, and the frame signal (11
5) is synchronized with the frame signal of the transmitting device.

[0004]

However, in such a conventional frame synchronization correction apparatus, a histogram indicating a timing difference is represented by a timing difference allowable value (threshold).
Since the correction processing is performed at a point in time beyond the limit, the timing jitter of the frame signal of the receiving apparatus with respect to the frame signal of the transmitting apparatus becomes extremely large. That is, the followability of the frame signal of the receiving device to the frame signal of the transmitting device is reduced.

In addition, since the UW pattern is always received to detect the timing difference between the frame signal of the transmitting device and the frame signal of the receiving device and correct the frame signal of the receiving device, it is necessary to correct the frame signal of the receiving device. When the UW pattern cannot be received for a long time, it is difficult to maintain synchronization between the frame signal of the transmitting device and the frame signal of the receiving device.

SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems, improves the followability of the frame signal of the receiving apparatus to the frame signal of the transmitting apparatus, and maintains the synchronization between the frame signal of the transmitting apparatus and the frame signal of the receiving apparatus. Aim.

[0007]

In order to solve the above-mentioned problems, according to the present invention, there is provided a known pattern detecting section for detecting a known transmission pattern from a received signal, a reference timer operated by a reference clock, and a known timer. A latch unit that holds the value of the reference timer in response to a detection pulse from the pattern detection unit, a flip-flop that holds the timer value latched at time (t-1), and a time lag between time (t-1) and time (t). A timing difference calculating unit including an adder for calculating a timing difference per fixed frame number by taking a difference between the correction values; a correction value calculating unit for calculating a correction value per frame from the calculated timing difference; A frame signal correction unit that corrects a frame signal by setting and maintains synchronization is provided.

With this configuration, it is possible to calculate a correction value per frame and correct frame synchronization between transmission and reception.

Also, a known pattern detection unit for detecting a known transmission pattern from a received signal, a reference timer operated by a reference clock, and a latch unit for holding a value of the reference timer by a detection pulse from the known pattern detection unit And a flip-flop holding the latched timer value at time (t-1), and calculating the difference between time (t-1) and time (t) to calculate the number of fixed frames or the timing difference per set frame A timing difference calculation unit having an adder, a memory unit for temporarily storing a timing difference per fixed frame number or a set frame number, and a timing difference calculation unit based on a known pattern detection presence / absence signal from a known pattern detection unit. Selector section for selecting either the data of the timing difference to be performed or the timing difference temporarily stored in the memory section. A correction value calculation unit for calculating a correction value per frame from the calculated timing difference and a structure in which a frame signal correcting section for holding the synchronization to correct the frame signal by setting the correction value.

With this configuration, the timing difference temporarily stored when no known pattern is detected due to a communication line disconnection or the like is read out, a correction value per frame is calculated, and the synchronization between the transmitting device and the receiving device is calculated. Can be retained.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention according to claim 1 of the present invention provides a base station operating with a reference clock based on a known pattern detection signal which detects a known pattern inserted in a control signal receivable at a fixed frame period. The timer value of the timer is latched, and a timer value difference per fixed frame number is calculated from the timer value latched at time (t-1) and the timer value latched at time (t) after the fixed frame period. The timer value difference is used as a timing difference per fixed number of frames between the time (t-1) and the time (t) of the transmission-side frame signal and the reception-side frame signal, and correction per frame is performed based on the timing difference. Calculate the value,
This is a frame synchronization correction method for correcting and maintaining frame synchronization between transmission and reception for each frame based on the correction value. Has the effect of minimizing.

According to a second aspect of the present invention, there is provided a known pattern detection unit for detecting a known transmission pattern from a received signal, a reference timer operated by a reference clock, and detection from the known pattern detection unit. A latch unit for holding the value of the reference timer by a pulse, a flip-flop for holding the timer value latched at time (t-1), and a timer value latched at time (t-1) and latching at time (t) A timing difference calculation unit including an adder that calculates a difference between the calculated timer value and a timing difference per fixed frame number, a correction value calculation unit that calculates a correction value per frame from the timing difference, A frame signal correction unit that corrects a frame signal by setting the correction value and maintains synchronization, and performs a correction process in units of one frame. Subjected to, it has the effect of suppressing the timing jitter of the frame signal of the receiving device with respect to the frame signal of the transmission apparatus to a minimum.

According to a third aspect of the present invention, there is provided a portable communication terminal having the frame synchronization correcting apparatus according to the second aspect, wherein timing jitter of the frame signal of the receiving apparatus with respect to the frame signal of the transmitting apparatus is minimized. It has the action of:

According to a fourth aspect of the present invention, there is provided a communication system having the portable communication terminal according to the third aspect, wherein the timing jitter of the frame signal of the receiving apparatus with respect to the frame signal of the transmitting apparatus is minimized. Having.

According to a fifth aspect of the present invention, a timer value of a reference timer operating on a reference clock is provided by a known pattern detection signal which detects a known pattern inserted in a control signal receivable at a fixed frame period. From the timer value and a timing reference value (a timer value in a state where there is no difference between the transmission side frame signal and the reception side frame signal) to calculate a timer value difference per fixed frame number, and calculate the timer value difference. Is a timing difference per fixed frame number between the transmission side frame signal and the reception side frame signal, and a correction value per frame is calculated from the timing difference;
This is a frame synchronization correction method for correcting and maintaining frame synchronization between transmission and reception for each frame based on the correction value. Has the effect of minimizing.

According to a sixth aspect of the present invention, there is provided a known pattern detection unit for detecting a known transmission pattern from a received signal, a reference timer operated by a reference clock, and detection from the known pattern detection unit. A latch unit for holding the value of the reference timer by a pulse; and obtaining a difference between the latched timer value and a timing reference value (a timer value when there is no difference between the transmission side frame signal and the reception side frame signal) to obtain a fixed frame number. A timing difference calculating section for calculating a timing difference per frame, a correction value calculating section for calculating a correction value per frame from the timing difference, and a frame signal correction for correcting a frame signal by setting the correction value and maintaining synchronization And a frame synchronization correction device that performs a correction process on a frame-by-frame basis, and It has an effect of minimizing the timing jitter of the frame signal of the device.

According to a seventh aspect of the present invention, there is provided a portable communication terminal having the frame synchronization correcting apparatus according to the sixth aspect, wherein timing jitter of the frame signal of the receiving apparatus with respect to the frame signal of the transmitting apparatus is minimized. It has the action of:

According to an eighth aspect of the present invention, there is provided a communication system having the portable communication terminal according to the seventh aspect, wherein the timing jitter of the frame signal of the receiving apparatus with respect to the frame signal of the transmitting apparatus is minimized. Having.

According to a ninth aspect of the present invention, in the frame synchronization correcting method according to the first or fifth aspect, the number of frames is arbitrarily changed externally for a control signal receivable at a fixed frame period. By setting, the reception interval of the control signal is to be a set frame period, the number of frames is arbitrarily set and the reception interval of the control signal is made variable,
This has the effect of minimizing the correction processing operation and reducing the power consumption of the device.

According to a tenth aspect of the present invention, in the frame synchronization correcting apparatus according to the second and sixth aspects, the number of frames is arbitrarily set externally from the frame counter and the reception interval of the control signal is set. A frame number variable register for setting a frame period, the number of frames is set arbitrarily, the reception interval of the control signal is made variable, the correction processing operation is minimized, and the power consumption of the device is reduced. Has an action.

According to an eleventh aspect of the present invention, there is provided a portable communication terminal having the frame synchronization correcting apparatus according to the tenth aspect, wherein the power consumption of the apparatus is reduced by minimizing the correction processing operation. Has an action.

According to a twelfth aspect of the present invention, there is provided a communication system having the portable communication terminal according to the eleventh aspect, which has an effect of minimizing a correction processing operation and reducing power consumption of the apparatus. Have.

According to a thirteenth aspect of the present invention, in the frame synchronization correcting method of the first, fifth and ninth aspects, a timing difference per fixed number of frames or a set number of frames is temporarily stored to detect a known pattern. A known pattern detection presence / absence signal having presence / absence information is used to read a timing difference temporarily stored when no known pattern is detected,
When the communication line disconnection (when the UW pattern is not detected) continues for a long time, a correction value per frame is calculated from the timing difference read from the memory, thereby realizing synchronization between the transmitting device and the receiving device. Have.

According to a fourteenth aspect of the present invention, in the frame synchronization correcting apparatus according to the second, sixth, or tenth aspect,
A memory unit for temporarily storing the timing difference per fixed frame number or set frame number, and a timing difference output from the timing difference calculation unit or a timing temporarily stored in the memory unit according to a known pattern detection presence / absence signal from the known pattern detection unit. And a selector unit for selecting either one of the differences.
When the pattern is not detected for a long time, the correction value per frame is calculated from the timing difference read from the memory, and the synchronization between the transmitting device and the receiving device is realized.

According to a fifteenth aspect of the present invention, there is provided a portable communication terminal having the frame synchronization correcting device according to the fourteenth aspect, wherein when a communication line disconnection (when UW pattern is not detected) continues for a long time, It has the effect of calculating a correction value per frame from the timing difference read from the memory, and realizing synchronization between the transmitting device and the receiving device.

According to a sixteenth aspect of the present invention, there is provided a communication system having the portable communication terminal according to the fifteenth aspect, wherein when the communication line disconnection (when the UW pattern is not detected) continues for a long time, the communication from the memory is performed. This has the effect of calculating a correction value per frame from the read timing difference and realizing synchronization between the transmitting device and the receiving device.

Hereinafter, an embodiment of the present invention will be described with reference to FIG.
This will be described in detail with reference to FIG.

(First Embodiment) A first embodiment of the present invention uses a known pattern detection signal generated by detecting a known pattern inserted in a control signal that can be received at a fixed frame period. The timer value of the reference timer operated by the reference clock is latched, and the timer value latched at the time (t-1) and the timer value latched at the time (t) after the fixed frame period are calculated per fixed frame number. And the timer value difference is defined as the timing difference per fixed number of frames between the time (t-1) and the time (t) between the transmission-side frame signal and the reception-side frame signal. This is a frame synchronization correction device that calculates a correction value for each frame, and corrects and holds frame synchronization between transmission and reception for each frame based on the correction value.

FIG. 1 is a block diagram of a frame synchronization correction apparatus according to a first embodiment of the present invention. In FIG.
301 is a reception signal. 302 is a reference clock. 303
Is a UW pattern detection unit, which detects a UW pattern from the received signal (301).
When a pattern is detected, a UW detection pulse of 305 is generated. 304 is a reference timer, which is a reference clock (30
It is counted by 2) and outputs the timer value of 306. 30
Reference numeral 7 denotes a latch unit which captures the timer value (306) of the reference timer (304) in response to the UW detection pulse (305). Reference numeral 311 denotes a timing difference calculation unit which calculates a timing difference (312) between the receiving device and the transmitting device from the latched timer value of 308 and the timer value (310) delayed by N frames by the flip-flop of 309.

Reference numeral 314 denotes a selector which switches the timing difference of 312 to output a or output b according to the operation mode of 313. The timing difference at the time of output a is defined as a timing difference initial value (315), and the timing difference at the time of output b is
With the timing difference (312) and 318 flip-flops,
By adding the timing difference (317) delayed by N frames, the total timing difference (31
6). A correction value calculation unit 319 calculates a correction value (320) per frame from the initial timing difference value (315) per N frames or the total timing difference (316). A frame signal correction unit 321 generates and corrects a frame signal by setting a reference clock (302) and a correction value (320).

The operation of the frame synchronization correction apparatus according to the first embodiment of the present invention configured as described above will be described with reference to the timing chart of FIG. 2 and the flowchart of FIG. First, a reception signal is received twice in an operation mode (313) (continuous reception operation) for the receiving apparatus to perform initial frame synchronization pull-in with respect to the transmitting apparatus. At time (t), the timer value when the first UW pattern is received is y (t), and at time (t + 1), the timer value when the second UW pattern is received is y (t + 1). Then, the timing difference (312) between the transmitting and receiving apparatuses in the N frame period which is the receiving period of the UW pattern is calculated as a timing difference initial value (315) y (t ₀ ) = y (t + 1) −y (t). I do. At this time, depending on the operation mode (313),
The selector (314) selects the output a. Then, a timing difference initial value per N frames (315) y
By using (t ₀ ), the correction value calculation unit (319) calculates the correction value (320) for each frame.

The flow of the correction value calculation processing will be described with reference to FIG. First, it is determined whether or not a timing difference actually exists. Here, when there is no timing difference, the processing of the correction value table creation 2 is performed. As a result, the correction value (320) T (n) for each frame becomes zero for all N frames.
(No pinch frame signal correction). On the other hand, when there is a timing difference, the timing difference ÷ calculates the integer part of the N frame, calculates the correction value J ₁ for the non-rounding up, and determines whether the timing difference is positive or negative. Next, the round-up correction value J
_2, to calculate a round-up amount correction value correction number C _2. When the timing difference is positive, J ₂ = J ₁ +1 and C ₂ = timing difference− (J ₁ × N frames). When the timing difference is negative, J ₂ = J ₁ −1 and C ₂ = − ( Timing difference (J ₁ × N frames)).

After the number of corrections C _{2 for the} round-up correction value is determined, the number of corrections for the no-round-up correction value is calculated as C ₁ = N frames−C ₂ . Then, the number of times C _{0 in} which the non-round-up correction value and the round-up correction value are alternately set in N frames.
Is calculated, a magnitude comparison is performed by C ₁ > C ₂ , and the smaller number is doubled. At this time, the correction value with the larger number of corrections is substituted for J ₀ . When the correction values J ₁ and J ₂ and the number of corrections C ₁ and C ₂ are obtained in this manner, the correction value table creation 1
Is performed.

First, the round-off correction value J ₁ and the round-up correction value J ₂ are substituted for T (n) by the number of alternating repetitions C ₀ , and then J ₀ is substituted for the remaining number of frames. Thus, a correction value table for N frames is completed,
Correction value (320) T (n) from correction value table for each frame
Is read out and set in the frame signal correction unit, so that the frame signal of the receiving device is corrected and synchronized.

Next, the operation after switching the operation mode (313) to the normal transmission / reception operation will be described. After switching the operation mode (313), time (t + 2), (t + 3) ...
Are respectively y (t + 2), y (t + 3)... When the UW pattern is received. After latching the timer value y (t + 2), the timing difference (312) between the transmitting and receiving apparatuses in the N frame period is calculated as y (t + 2) −y (t + 1). At this time, the selector (314) selects the output b according to the operation mode (313). Here, the total timing difference (317) y (t ₀ ) held in the flip-flop (318)
And the timing difference (312) y (t + 2) −y (t + 1) are added to calculate the total timing difference (316) y (t ₁ ) at the present time. Then, by using the total timing difference (314) y (t1) per N frames, the correction value calculation unit (31
In 9), a correction value (320) for each frame is calculated.
After latching the timer value y (t13), the timing difference (312) between the transmitting and receiving apparatuses in the N frame period is calculated as y (t + 3) −y (t +
Calculated as 2).

Here, the total timing difference (317) y (t ₁ ) held in the flip-flop (318) and the timing difference (312) y (t + 3) −y (t + 2) are added. Thus, the total timing difference (316) y (t ₂ ) at the present time is calculated. Then, the total timing difference per N frame (314) y (t ₂ )
Is used to calculate a correction value (320) for each frame in the correction value calculation unit (319). Thereafter, the same operation is performed when the timer value becomes y (t + 4), y (t + 5), y (t + 6). The operation of the correction value calculation processing is the same as described above.

An example will be described in which numerical values are actually applied to the flow of the correction value calculation processing. It is assumed that the UW pattern is received at a frame period (N = 24) with a total timing difference (316) of 13 (the unit is the minimum resolution of the timer value: B symbol, B clock, etc.). Therefore, J ₁ = 0, C ₁ = 11, J ₂
= 1, C ₂ = 13, J ₀ = J ₂ = 1, and the correction value table is 010101010101010101010111 (when the flow shaded portion of the correction value table creation 1 is used) or 10101010101010
1010101011 (when the shaded portion in the flow of the correction value table creation 1 is used).

FIG. 4 shows the state of timing jitter when a correction process is performed using this correction value. In the case of FIG.
This is an example in which a timing difference 14 occurs in the next 24 frame periods with respect to the correction amount 13 of the frame period. In this case, the timing difference (13 + difference 1) is corrected in the next 24 frames, and the same processing is performed thereafter. As can be seen from FIG. 4, according to the present invention, it is possible to suppress the timing jitter extremely small as compared with the conventional device.

As described above, according to the first embodiment of the present invention, the frame synchronization correction device detects the known pattern generated by detecting the known pattern inserted in the control signal receivable at a fixed frame period. In response to the signal, the timer value of the reference timer operating on the reference clock is latched, and the time (t−
Based on the difference between the latched timer value in 1) and the latched timer value at time (t) after the fixed frame period, a difference in timer value per fixed frame number is calculated, and the calculated difference is transmitted to the transmitting side. A timing difference per fixed number of frames between the time (t-1) and the time (t) of the frame signal and the frame signal on the receiving side is set, and a correction value per frame is used to correct the timing difference for each frame. Is calculated and the frame synchronization between transmission and reception is corrected and held, so that the correction process can be performed in units of one frame to minimize the timing jitter of the frame signal of the receiving apparatus with respect to the frame signal of the transmitting apparatus. .

(Second Embodiment) In a second embodiment of the present invention, a known pattern detection signal generated by detecting a known pattern inserted in a control signal receivable at a fixed frame period is used. Latch the timer value of the reference timer that operates on the reference clock, and calculate the timer value per fixed frame number from the timer value and the timing reference value (the timer value when there is no difference between the transmission frame signal and the reception frame signal). A difference is calculated, a timer value difference is set as a timing difference per fixed frame number between the transmission side frame signal and the reception side frame signal, and a correction value per frame is calculated from the timing difference. 1
This is a frame synchronization correction device that corrects and holds for each frame.

FIG. 5 is a block diagram of a frame synchronization correcting apparatus according to a second embodiment of the present invention. In FIG.
701 is a received signal. 702 is a reference clock. 703
Is a UW pattern detection unit, which detects the UW pattern from the received signal (701).
When a pattern is detected, a 705 UW detection pulse is generated. Reference numeral 704 denotes a reference timer, and a reference clock (702)
And the timer value of 706 is output. Reference numeral 707 denotes a latch unit which captures the timer value (706) of the reference timer (704) in response to the UW detection pulse (705). Reference numeral 711 denotes a timing difference calculation unit, which is provided with the latched timer value of 708 and 723.
The timing difference (712) between the receiving device and the transmitting device is calculated from the timing reference value. Numeral 724 denotes a flip-flop which delays the timing difference (716) by N frame periods and outputs it as a positive timing difference (725) and a negative timing difference (726).

A selector 727 selects and outputs the positive timing difference (725) of the input a (725) and the negative timing difference (726) of the input b (726) according to the operation mode of the 713. Reference numeral 716 denotes a total timing difference, which is determined by the sum of the timing difference of 717 delayed by N frame periods and the current timing difference. Reference numeral 719 denotes a correction value calculation unit which calculates a correction value (7) per frame from the total timing difference (716) per N frames.
20) is calculated. A frame signal correction unit 721 generates and corrects a frame signal by setting a reference clock (702) and a correction value (720).

The operation of the frame synchronization correcting apparatus according to the second embodiment of the present invention will be described with reference to the timing chart of FIG. First, a reception signal is received twice in an operation mode (713) (continuous reception operation) for the reception apparatus to perform initial frame synchronization pull-in with respect to the transmission apparatus. At this time, it is assumed that the selector (727) has selected the input b. At time (t), the timer value when the first UW pattern is received is represented by y.
(t), and the timing difference calculator (711) calculates the difference between the timing reference value (723) and the timer value y (t). Time (t
+1), the timer value when the second UW pattern is received is defined as y (t + 1), and the timing difference calculation unit (711) calculates the timing reference value (723) and the timer value y (t + 1). And take the difference.

Then, the negative timing difference (726) (-y (t) -y (b) before the N-frame period at the current time (t + 1).
ase)) and the timing difference (712) (y
(t + 1) −y (base)) to calculate the total timing difference (716) y (t ₀ ) per N frame periods.
Then, the total timing difference per N frames (715) y
By using (t ₀ ), the correction value calculation unit (719) calculates the correction value (720) for each frame. The flow of the correction value calculation process is the same as that of the first embodiment shown in FIG.

Next, the operation after switching the operation mode (713) to the normal transmission / reception operation will be described. After switching the operation mode (313), time (t + 2), (t + 3) ...
Are respectively y (t + 2), y (t + 3)... When the UW pattern is received. At this time, the reselector (727) selects the input a according to the operation mode (713). After latching the timer value y (t + 2), the timing difference (712) between the transmitting and receiving apparatuses in the N frame period is calculated as y (t + 2).
Calculate as −y (base). Here, the total timing difference (725) y (t ₀ ) and the timing difference (712) y (t + 2) −N frames before the N-frame period held in the flip-flop (724).
By adding y (base), the total timing difference (716) y (t ₁ ) at the present time is calculated.

Then, a correction value calculation unit (719) is obtained by using the whole-day evening difference (714) y (t ₁ ) per N frames.
Calculates a correction value (720) for each frame. After latching the timer value y (t + 3), the timing difference (712) between the transmitting and receiving apparatuses in the N frame period is calculated as y (t + 3) −y (base).
Is calculated as Here, the total timing difference (725) before the N-frame period held in the flip-flop (724)
By adding y (t ₁ ) and the timing difference (712) y (t + 3) −y (base), the total timing difference at the present time (716) y (t ₂ )
Is calculated. Then, by using the total timing difference (714) y (t ₁ ) per N frames, the correction value calculation unit (71
In step 9), a correction value (720) for each frame is calculated.
Thereafter, the same operation is performed when the timer value becomes y (t + 4), y (t + 5), y (t + 6). The operation of the correction value calculation processing is the same as that of the first embodiment shown in FIG.

As described above, according to the second embodiment of the present invention, the frame synchronization correction device performs the known pattern detection generated by detecting the known pattern inserted in the control signal receivable at a fixed frame period. The signal latches the timer value of the reference timer that operates on the reference clock, and calculates the difference between the latched timer value and the timing reference value (the timer value when there is no difference between the transmitting frame signal and the receiving frame signal). Calculate the difference between the timer values per fixed frame number, and use the calculated difference as the timing difference per fixed frame number between the transmitting frame signal and the receiving frame signal. In order to correct this timing difference for each frame, Since the correction value per frame is calculated and the frame synchronization between transmission and reception is corrected and held, the correction processing is executed in units of one frame. , It is possible to suppress the timing jitter of the frame signal of the receiving device with respect to the frame signal of the transmission apparatus to a minimum.

(Third Embodiment) In a third embodiment of the present invention, a control signal which can be received at a fixed frame period is variably set from the outside to arbitrarily set a control signal. Is a frame synchronization correction device that can set the reception interval of a frame as a set frame period.

FIG. 7 is a block diagram of a frame synchronization correcting device according to a third embodiment of the present invention. In FIG.
901 is a reception signal. 902 is a reference clock. 903
Is a UW pattern detection unit, which detects the UW pattern from the received signal (901).
When a pattern is detected, a 905 UW detection pulse is generated. Reference numeral 904 denotes a reference timer, and a reference clock (902)
And the timer value of 906 is output. Reference numeral 907 denotes a latch unit which captures the timer value (906) of the reference timer (904) in response to the UW detection pulse (905). Reference numeral 911 denotes a timing difference calculation unit, which stores the timer value of 908 and 909
The timing difference (912) between the receiving device and the transmitting device is calculated from the timer value (910) delayed by (N × k) frames by the flip-flop.

Reference numeral 914 denotes a selector which depends on the operation mode of the 913.
The timing difference of 2 is switched to output a or output b. The timing difference at the time of the output a is defined as a timing difference initial value (915), and the timing difference at the time of the output b is (N × k) by the timing difference (912) and the 918 flip-flop.
By adding the timing difference (917) delayed by the frame, the total timing difference (916) per (N × k) frame is obtained. Reference numeral 919 denotes a correction value calculation unit, and (N × k)
A correction value per frame (920) is calculated from the timing difference initial value per frame (915) or the total timing difference (916). 921 is a frame signal correction unit,
A frame signal is generated and corrected by setting the reference clock (902) and the correction value (920).

The third embodiment of the present invention is based on the configuration shown in the first embodiment.
Frame number variable register (929) and frame counter (9
By providing 31), the frame period of the received signal can be arbitrarily controlled externally by the frame parameter (928).

The operation of the frame synchronization correcting apparatus according to the third embodiment of the present invention configured as described above will be described with reference to the timing chart of FIG. First,
The reception frame period of the reception signal is set by the frame parameter (928). As a result, data is set in the frame number variable register (929), and the frame counter (931) operated by the frame signal (922) is set to (N
Xk) Start operation at frame period. Hereinafter, the operation description and the basic operation described in the first embodiment are the same.

Here, the frame parameter 2 will be described. The reception signal is received twice in the operation mode (913) (continuous reception operation) for the reception device to perform the initial frame synchronization pull-in with respect to the transmission device. At time (t), the timer value when the first UW pattern is received is y (t), and at time (t + 1), the frame period of the received signal is set to 2N, so that the correction process is not performed. . At time (t + 2), the timer value when the UW pattern is received for the second time is y (t + 2), and the timing difference (912) between the transmitting and receiving apparatuses in the 2N frame period, which is the UW pattern receiving period, is the timing difference. Initial value (915) Calculated as y (t ₀ ) = y (t + 2) −y (t). At this time, the selector (914) selects the output a according to the operation mode (913). And the initial value of the timing difference per 2N frames (915)
By using y (t ₀ ), the correction value calculation section (919) calculates a correction value (920) for each frame.

The flow of the correction value calculation process is the same as that of the following process by setting the N frames shown in FIG. 3 to 2N frames. First, it is determined whether or not a timing difference actually exists. Here, when there is no timing difference,
The processing of the correction value table creation 2 is performed. This gives 1
The correction value (920) T (n) for each frame becomes 0 for all 2N frames (that is, no frame signal correction). On the other hand, when there is a timing difference, the timing difference is calculated by calculating the integer part of the 2N frame and calculating the correction value J ₁ for the value without rounding up.
Determine whether the timing difference is positive or negative. Next, a round-up correction value J ₂ and a round-up correction value correction frequency C ₂ are calculated.

When the timing difference is positive, J ₂ = J ₁ +1 and C ₂ = timing difference− (J ₁ × 2N frames). When the timing difference is negative, J ₂ = J ₁ -1, C ₂ = − (Timing difference− (J ₁ × 2N frames)).

After the number of corrections C _{2 for the} round-up correction value is determined, the number of corrections for the no-round-up correction value is calculated as C ₁ = 2N frames−C ₂ . Then, the number of times C in which the non-round-up correction value and the round-up correction value are alternately set in the 2N frame.
_In order to calculate ₀ , the magnitudes are compared by C ₁ > C ₂ , and the smaller number is doubled. At this time, the correction value with the larger number of corrections is substituted for J ₀ . When the correction values J ₁ and J ₂ and the number of corrections C ₁ and C ₂ are obtained in this manner, the correction value table creation 1
Is performed.

First, the round-off correction value J ₁ and the round-up correction value J ₂ are substituted for T (n) by the number of alternating repetitions C ₀ , and then J ₀ is substituted for the remaining frames.
In this way, a correction value table for 2N frames is completed, and the correction value (920) T (n) is read out from the correction value table for each frame and set in the frame signal correction unit, whereby the frame signal of the receiving apparatus is corrected and synchronized. Will be retained.

Next, the operation after switching the operation mode (913) to the normal transmission / reception operation will be described. After the operation mode (913) is switched, similarly, the reception signal is received at the 2N frame period, and the timer values when the UW patterns are received at times (t + 4), (t + 6),.
4), y (t + 6) ... After latching the timer value y (t + 4),
The timing difference (912) between the transmitting and receiving apparatuses in the 2N frame period is calculated as y (t + 4) -y (t + 2). At this time, the selector (914) selects the output b according to the operation mode (913).

Here, the total timing difference (917) y (t ₀ ) held in the flip-flop (918) and the timing difference (912) y (t + 4) −y (t + 2) are added. To calculate the total timing difference (916) y (t ₁ ) at the present time. And the total timing difference per 2N frame (914) y
By using (t ₁ ), the correction value calculation unit (919) calculates the correction value (920) for each frame. Timer value y
After latching (t + 6), the timing difference (912) between the transmitting and receiving apparatuses in the 2N frame period is calculated as y (t + 6) −y (t + 4). Here, by adding the total timing difference (917) y (t ₁ ) held in the flip-flop (918) and the timing difference (912) y (t + 6) −y (t + 4), Is calculated (916) y (t ₂ ).

Then, by using the total timing difference (914) y (t ₂ ) per 2N frames, the correction value calculation unit (9
In step 19), a correction value (920) for each frame is calculated. Thereafter, the timer values y (t + 8), y (t + 10), y (t + 12) ...
The same operation is carried out when. The operation of the correction value calculation processing is the same as described above.

As described above, in the third embodiment of the present invention, the frame synchronization correction device is configured to arbitrarily set the number of frames arbitrarily externally for a control signal that can be received at a fixed frame period. Since the control signal reception interval is set to the set frame period, the number of frames is arbitrarily set and the control signal reception interval is made variable to minimize the correction processing operation and reduce the power consumption of the device. realizable.

(Fourth Embodiment) In a fourth embodiment of the present invention, a timing difference per fixed number of frames or a set number of frames is temporarily stored, and a known pattern detection information having information on whether or not a known pattern is detected is provided. This is a frame synchronization correction device capable of reading a timing difference temporarily stored in the absence of a known pattern detection by an existence signal.

FIG. 9 is a block diagram of a frame synchronization correcting apparatus according to a fourth embodiment of the present invention. In FIG.
1101 is a received signal. 1102 is a reference clock. 11
03 is a UW pattern detection unit, which detects U from the received signal (1101).
When a W pattern is detected, a UW detection pulse of 1105 is generated. Reference numeral 1104 denotes a reference timer, and a reference clock (11
02) and outputs the timer value of 1106. 11
Reference numeral 07 denotes a latch unit which captures the timer value (1106) of the reference timer (1104) in response to the UW detection pulse (1105). 1111
Is a timing difference calculation unit that calculates a timing difference (1112) between the receiving device and the transmitting device from the latched timer value of 1108 and the timing reference value of 1123.

Reference numeral 1124 denotes a flip-flop which delays the timing difference (1116) by N frame periods and outputs the result as a positive timing difference (1125) and a negative timing difference (1126). 1127 is a selector for input a depending on the operation mode of 1113
And the negative timing difference (1126) of the input b (1125) and the output a are selected and output. Reference numeral 1116 denotes a total timing difference, which is determined by the sum of the timing difference delayed by N frame periods of 1117 and the current timing difference.
Reference numeral 1119 denotes a correction value calculation unit which calculates a correction value (112) per frame from the total timing difference (1116) per N frames.
0) is calculated. Reference numeral 1121 denotes a frame signal correction unit which generates and corrects a frame signal by setting a reference clock (1102) and a correction value (1120).

The fourth embodiment of the present invention is based on the configuration shown in the second embodiment, and has the following features.
By providing the memory unit (1133) for storing the total timing difference (1116) per N frames, even if the communication line disconnection (when UW pattern is not detected) continues for a long time, the timing difference read from the memory can be obtained. Can be used to calculate a correction value per frame.

The operation of the frame synchronization correcting apparatus according to the fourth embodiment of the present invention having the above-described configuration will be described with reference to the timing chart of FIG. In a basic operation (a state in which a UW pattern can be detected), the operation is the same as that described in the second embodiment. In the present embodiment, UW
In a state where the pattern is detected, one or a plurality of actually calculated timing differences per N frames (1116) are stored in the memory as correction history information.
From this, when the line between transmission and reception is in an abnormal state (when the UW pattern is not detected), the known pattern detection unit (11
The known pattern detection presence / absence signal (1135) output from 03) indicates an undetected state, and the selector (1128) switches to the memory side (input b). As a result, the correction history information is read from the memory unit, and even when the UW pattern is not detected, the correction can be performed with a value very close to the actual timing shift, and the synchronization state between the transmitting and receiving apparatuses is maintained. be able to. After the line status is restored, the selector (11
28) is switched to the input a, and the frame correction and synchronization processing are performed again in the normal line state. Also, the correction history information in the memory unit is sequentially updated, and the correction history information is updated to prepare for a line abnormal state.

As described above, in the fourth embodiment of the present invention, the frame synchronization correction device temporarily stores the timing difference per fixed frame number or set frame number,
Since the timing difference temporarily stored when no known pattern is detected is read based on a known pattern detection presence / absence signal having information on the presence / absence of known pattern detection, the communication line disconnection (U
Even when the (W pattern is not detected) continues for a long time, the correction value per frame can be calculated from the timing difference read from the memory, and the synchronization between the transmitting device and the receiving device can be realized.

[0068]

As described above, according to the present invention, since the correction processing is performed on a frame basis, the timing jitter of the frame signal of the receiving apparatus with respect to the frame signal of the transmitting apparatus can be minimized. Can be

Further, by arbitrarily setting the number of frames and varying the reception interval of the control signal, the correction processing operation can be minimized, so that the effect of reducing the power consumption of the apparatus can be obtained.

Further, communication line disconnection (when UW pattern is not detected)
Since the correction value per frame can be calculated from the timing difference read out from the memory even when is continued for a long time, it is possible to obtain an effect that synchronization between the transmitting device and the receiving device can be realized.

[Brief description of the drawings]

FIG. 1 is a functional block diagram of a frame synchronization correction device according to a first embodiment of the present invention;

FIG. 2 is a timing chart according to the first embodiment of the present invention;

FIG. 3 is a flowchart according to the first embodiment of the present invention;

FIG. 4 is a diagram showing timing jitter due to correction processing according to the first embodiment of the present invention;

FIG. 5 is a functional block diagram of a frame synchronization correction device according to a second embodiment of the present invention;

FIG. 6 is a timing chart according to the second embodiment of the present invention;

FIG. 7 is a functional block diagram of a frame synchronization correction device according to a third embodiment of the present invention;

FIG. 8 is a timing chart according to the third embodiment of the present invention;

FIG. 9 is a functional block diagram of a frame synchronization correction device according to a fourth embodiment of the present invention;

FIG. 10 is a timing chart according to the fourth embodiment of the present invention;

FIG. 11 is a functional block diagram of a conventional frame synchronization correction device.

FIG. 12 is a timing chart in a conventional frame synchronization correction device.

[Explanation of symbols]

101,301,701,901,1101 Received signal 102,302,702,902,1102 Reference clock 103,303,703,903,1103 UW (known) pattern detection unit 104,304,704,904,1104 Reference timer 105,305,705,905,1105 UW (known) pattern detection pulse 106,306,706,906,1106 Reference timer timer unit 708,107 1108 Timer value of reference timer latched 109 Histogram calculation unit for UW pattern detection time 110 Histogram calculation result 111 Timing correction value detection unit 112 Correction value detection result 113 Timing allowable value 114 Frame signal generation unit 115,322,722,922,1122 Frame signal 311,711,911,1111 Timing Difference calculator 312,712,912,1112 Timing difference 309,318,724,909,918,1124 Flip-flop 316,716,916,1116,1134,1136 Total timing difference 314,727,914,1127,1128 Selector 310,317,717,725,726,910,917,1117,1125,1126 Delayed timing difference 319,120,920 Correction value 321, 721,921,1121 Frame signal correction unit 313,713,913,1113 Operation mode 723,1123 Timing reference value 315,915 Timing difference initial value 928 Frame parameter 929 Frame number variable register 930 Frame number variable register value 931 Frame counter 932 Frame counter value 1133 Memory unit 1135 Known pattern Detection presence / absence signal

Claims (16)

[Claims] 1. A timer value of a reference timer operated by a reference clock is latched by a known pattern detection signal which detects a known pattern inserted in a control signal receivable at a fixed frame period, and a time (t-1) A timer value difference per fixed number of frames is calculated from the timer value latched at the time and the timer value latched at the time (t) after the fixed frame period, and the timer value difference is calculated based on the transmission side frame signal and the reception side. As a timing difference per fixed number of frames between the time (t-1) and the time (t) of the frame signal, a correction value per frame is calculated from the timing difference, and the frame synchronization between transmission and reception is calculated based on the correction value. 1
A frame synchronization correction method characterized by correcting and holding for each frame. 2. A known pattern detector for detecting a known transmission pattern from a received signal, a reference timer operated by a reference clock, and a value of the reference timer held by a detection pulse from the known pattern detector. A latch section,
A flip-flop that holds the timer value latched at time (t-1), and a difference between the timer value latched at time (t-1) and the timer value latched at time (t) is calculated as a fixed frame number. A timing difference calculation unit including an adder for calculating a timing difference between
A frame synchronization correction device comprising: a correction value calculation unit that calculates a correction value per frame; and a frame signal correction unit that corrects a frame signal by setting the correction value and maintains synchronization. 3. A portable communication terminal comprising the frame synchronization correction device according to claim 2. 4. A communication system comprising the mobile communication terminal according to claim 3. 5. A timer value of a reference timer that operates on a reference clock is latched by a known pattern detection signal that detects a known pattern inserted in a control signal receivable at a fixed frame period, and the timer value and a timing reference A timer value difference per fixed number of frames is calculated from the value (the timer value when there is no difference between the transmission side frame signal and the reception side frame signal), and the timer value difference is calculated based on the transmission side frame signal and the reception side frame signal. Frame synchronization correction, wherein a correction value per frame is calculated from the timing difference, and a frame synchronization between transmission and reception is corrected and held for each frame by the correction value. Method. 6. A known pattern detection unit for detecting a known transmission pattern from a received signal, a reference timer operated by a reference clock, and holding a value of the reference timer by a detection pulse from the known pattern detection unit. A latch section,
A timing difference calculation unit that calculates a difference between the latched timer value and a timing reference value (a timer value in a state where there is no difference between the transmission-side frame signal and the reception-side frame signal) and calculates a timing difference per fixed frame number; A frame synchronization correction apparatus comprising: a correction value calculation unit that calculates a correction value per frame from a timing difference; and a frame signal correction unit that corrects a frame signal by setting the correction value and maintains synchronization. . 7. A mobile communication terminal comprising the frame synchronization correction device according to claim 6. 8. A communication system comprising the mobile communication terminal according to claim 7. 9. The control signal reception interval is set to a set frame period by externally setting a control signal receivable at a fixed frame period by arbitrarily changing the number of frames. A frame synchronization correction method according to any one of the first to fifth aspects. 10. The apparatus according to claim 2, further comprising: a frame counter unit; and a frame number variable register that externally sets an arbitrary number of frames and sets a control signal reception interval to a set frame period. Frame synchronization correction device. 11. A portable communication terminal comprising the frame synchronization correction device according to claim 10. 12. A communication system comprising the mobile communication terminal according to claim 11. 13. A timing difference per fixed number of frames or a set number of frames is temporarily stored, and a timing difference temporarily stored in the absence of a known pattern is detected by a known pattern detection presence / absence signal having information on the presence / absence of detection of a known pattern. 10. The frame synchronization correction method according to claim 1, wherein reading is performed. 14. A memory unit for temporarily storing a timing difference per fixed frame number or a set frame number, and a known pattern detection presence / absence signal from a known pattern detection unit.
11. The frame synchronization according to claim 2, further comprising: a selector unit for selecting either data of the timing difference output from the timing difference calculation unit or the timing difference temporarily stored in the memory unit. Correction device. 15. A portable communication terminal comprising the frame synchronization correction device according to claim 14. 16. A communication system comprising the mobile communication terminal according to claim 15.