JP3071338B2 - Super frame transmission timing specification device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to, for example, the Radio System Development Center (hereinafter referred to as "RCR").
Standards (draft) First Edition RCR STD-28 (Heisei 5
March 17, 2005) (hereinafter "RCR STD-28")
That. The present invention relates to a superframe transmission timing specifying device for specifying a superframe transmission timing of each base station in a digital cordless telephone system defined in (1).

[0002]

2. Description of the Related Art In recent years, in a cordless telephone system, a digital system has been studied in accordance with an increase in subscribers and a demand for confidentiality.

[0003] This digital cordless telephone system is:
As shown in FIG. 2, it is composed of a base station CS and a mobile station PS. Both can communicate with each other via a wireless section interface. Also, the base station CS
For example, it is connected to the exchange SW via an ISDN interface.

[0004] The radio section interface uses the RCR ST
D-28. In this wireless section interface, a 4-channel multiplexing TDMA / TDD system is adopted as an access system.

In the 4-channel multiplexing TDMA / TDD system, as shown in FIG. 3, signals are transmitted in a time division manner from the base station CS to the mobile station PS in the first half of each TDMA / TDD frame period, and in the second half, Mobile station PS to base station C
A signal is transmitted to S in a time-division manner. In this case, 1TDMA
The / TDD frame period is set to 5 ms, and the length of one slot is set to 625 μs.

[0006] The base station CS or the mobile station PS is a link channel.
The channel used in the establishment phase is called LCCH (Logical Control Channel). This LCCH has a superframe structure. All transmission / reception timings of control physical slots such as intermittent transmission of the base station CS are generated based on this superframe.

[0007] The superframe is defined as all L
It refers to the minimum period of the downlink LCCH that specifies the slot position of the CCH element. Here, the LCCH element is a BCCH (broadcasting channel) used in the system, a PCH (broadcasting channel) corresponding to all paging groups, and a fixedly inserted SCCH (channel for individual cell) and USCCH. (Optional).

[0008] The BCCH means that the mobile station PS is transmitted from the base station CS.
And a downlink one-way channel for broadcasting control information. The control information includes information on a channel structure, system information, and the like. The mobile station PS can know the head position of the superframe by detecting this BCCH.

The PCH is a point-multipoint downlink one-way channel for simultaneously transferring the same information from a base station CS to a mobile station PS over a single cell or a wide area (paging area) of a plurality of cells. .

[0010] The SCCH is a point-to-point bidirectional channel for transferring information required for call connection between the base station CS and the mobile station PS. In this SCCH, independent information is transferred for each cell.

FIG. 4 shows an example of the configuration of a superframe.

The illustrated superframe has one BCC.
H, one SCCH, and one PCH. In this case, the superframe transmission cycle is 1.5 seconds.
, And the interval between the channels is set to 500 ms.

In the RCR STD-28, the superframe is intermittently transmitted from the base station CS to the mobile station PS. In this case, conventionally, a superframe is transmitted at an arbitrary timing for each base station CS.

[0014]

However, with such a configuration, when the number of base stations CS increases, there is a problem that the transmission timing of superframes transmitted from each base station CS is likely to overlap.

[0015] Therefore, the present invention provides a method for increasing the number of base stations,
It is an object of the present invention to provide a superframe transmission timing designating apparatus that can prevent superframe transmission timings of base stations from overlapping.

[0016]

In order to achieve the above object,
Therefore, the present invention includes an exchange control means,
From the base stations connected to the mobile station to the mobile station.
Superframe of cordless telephone system that sends out
The following components are required in the
Be prepared. That is, in the present invention, (1) the plurality of
Each of the base stations is superframed by the switching control means.
For selecting slot numbers that specify
Base station-side reference signal or transmission slot used as a foundation
After generating the candidate number, this base station side reference signal or transmission
A slot for transmitting an outgoing slot candidate number to the exchange control means.
From the exchange number requesting means and the exchange control means.
At the timing corresponding to the slot number,
Transmission timing control unit that controls the transmission of frames
And the super timing under the control of the transmission timing control unit.
And (2) the plurality of bases.
From the base station, the base station-side reference signal or transmission slot candidate
The exchange control means for receiving a number,
The switching reference signal, which is the reference signal generated in the
Switching-side reference signal generating means,
Slot number selecting means for selecting, and at least
Transmission time slot for notifying the lot number to the corresponding base station
And (3) the slot number selecting means.
Corresponds to a case where the exchange control means receives a base station side reference signal.
In the case, the base station side transmitted from the plurality of base stations
The serial number generated in time series according to the phase of the reference signal
From the middle, fingers at different timings on the exchange side reference signal
Output the corresponding number as the slot number.
When receiving the transmission slot candidate number,
A different number for each base station from the transmission slot number candidates
Selected and output as the slot number.
And (4) further connecting the exchange control means to the base station.
The following is an ISDN input for notifying the transmission time slot.
Interface.

[0017]

According to the above, the common exchange control means is connected to
Each base station sends the base station side reference signal to the exchange control means.
When transmitting, the slot number selecting means of the exchange control means
Is the base station side reference transmitted from the plurality of base stations.
In the sequence number generated in time series according to the phase of the signal
Specified at different timings on the exchange side reference signal.
To output the corresponding number as the slot number,
Regardless of the phase relationship of the base station side reference signal of each base station.
And the transmission time that does not overlap with the slot number
Slots can be specified.

On the other hand, each connected to the common exchange control means
The base station sends the transmission slot candidate number to the exchange control means.
When transmitting, the slot number selecting means transmits the
Select a different number for each base station from slot number candidates
And outputs it as the slot number. And each base station
The transmission timing control section in
Transmit the superframe at the corresponding timing
Control. That is, the transmission timing of each base station is
Centralized management by exchange control means
The exchange between each base station and the exchange control means
Based on.

[0019]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of one embodiment of the present invention.

In this embodiment, the exchange SW uses each base station C
S superframe transmission timings are set so as not to overlap each other, and this transmission timing
W notifies each base station CS.

Further, in this embodiment, the base station C
It is set independently for each S.

Further, in this embodiment, the exchange SW manages the superframe transmission timing (transmission slot) of each base station CS.

That is, in FIG. 1, the base station CS
A reference signal generator 11, a slot number allocator 12,
It has a superframe sending unit 13 and a transmitting / receiving unit 14. Further, the exchange SW includes a reference signal generation unit 21, a transmission timing setting unit 22, a slot number allocation unit 23
, A transmission slot number detecting unit 24 and a transmitting / receiving unit 25.

The reference signal generator 11 of the base station CS outputs a reference signal R1 as a reference when the base station CS transmits a superframe. The cycle of the reference signal R1 is set to 1.5 s, which is the same as the superframe sending cycle.

The slot number allocating section 12 allocates a number N to each slot with reference to the reference signal R1 output from the reference signal generating section 11.

The superframe transmitting section 13 transmits a superframe to a mobile station PS (not shown). The superframe transmitting section 13 compares the slot number N allocated by the slot number allocating section 12 with the transmission slot number Na transmitted from the exchange SW, and starts transmitting a superframe when the two coincide with each other.

The transmission / reception unit 14 transmits the reference signal R1 output from the reference signal generation unit 11 to the exchange SW, and sends the transmission slot number Na transmitted from the exchange SW.
And supplies it to the superframe sending unit 13.

The reference signal generator 21 of the switch SW outputs a reference signal R2 which is used as a reference when setting the superframe transmission timing T of each base station CS. The cycle of the reference signal R2 is also set to 1.5 s, which is the same as the superframe sending cycle.

The transmission timing setting section 22 sets the superframe transmission timings T of the respective base stations CS so as not to overlap each other with reference to the reference signal R2 output from the reference signal generation section 21.

The slot number allocating unit 23 transmits each base station C
The number N is assigned to each slot based on the reference signal R1 sent from S.

The transmission slot number detecting section 24 assigns the transmission slot number Na having the transmission timing T set by the transmission timing setting section 21 to the slot number allocating section 2.
3 is detected from among the slot numbers N allocated.

The transmission / reception section 25 receives the reference signal R1 sent from the base station CS, supplies the reference signal R1 to the slot number allocating section 23,
3 is transmitted to the base station CS.

The operation of the above configuration will be described with reference to FIG.

In the following description, it is assumed that there are two base stations CS (1) and (2) as base stations CS.

From the reference signal generator 21 of the exchange SW,
A reference signal R2 as shown in FIG. As a result, the transmission timing setting unit 22 sets each of the base stations CS (1) and CS (2) based on the reference signal R2.
Superframe transmission timing T (1), T (2)
Is set. FIG. 5B shows the transmission timing T
Examples of (1) and (2) are shown.

The set transmission timing T (1), T
(2) is notified to the corresponding base stations CS (1) and CS (2). In this case, the transmission timing T (1), T
(2) is notified as a difference from the reference signals R1 (1) and R1 (2) of the corresponding base stations CS (1) and CS (2).

That is, each base station CS (1), CS
The reference signal R output from the reference signal generator 11 of (2)
1 (1) and R1 (2) are sent from the transmission / reception unit 13 to the exchange SW via the ISDN interface. In this case, the reference signals R1 (1) and R1 (2) correspond to the ISDN basic user / network interface specification (CCITT I.43).
In 0), transmission is performed using a Q channel defined as an additional channel.

The data of the TCH (information channel) for transferring the user information is transmitted using the B channel. Control data is transmitted using the D channel.

FIGS. 5 (c) and 5 (e) show each base station CS
(1), reference signal R1 output from CS (2)
(1) and R1 (2) are shown. As shown, each reference signal R
1 (1) and R1 (2) are output at arbitrary timings.

Reference signal R1 sent to exchange SW
(1) and R1 (2) are received by the transmitting / receiving unit 25,
This is supplied to the slot number allocating unit 23. This allows
The number N is assigned to the slot of each base station CS (1), CS (2) based on each reference signal R1 (1), R1 (2).
(1) and N (2) are allocated. FIG. 5 (d), (f)
, The slot numbers N (1) of the base stations CS1 and CS2,
N (2).

The slot numbers N (1) and N (2) are
This is supplied to the transmission slot number detection unit 24. As a result, transmission slot numbers Na (1) and Na (2) that match transmission timings T (1) and T (2) are detected for each of the base stations CS (1) and CS (2).

In the case of FIG. 5, for the base station CS (1), the transmission timing T (1) matches the slot of the slot number 8, so that the slot number 8 is detected as the transmission slot number Na (1). You. Similarly, base station C
As for S (2), since the transmission timing T (2) matches the slot of slot number 11, the slot number 11 is detected as the transmission slot number Na (2).

The detected transmission slot number Na (1),
Na (2) is transmitted from transmitting / receiving section 25 to corresponding base stations CS1 and CS2 via the ISDN interface.
In this case, the transmission slot numbers Na (1), Na (1)
(2) is transmitted using the D channel.

Transmission slot numbers Na (1), Na (2)
Indicates the distance from the corresponding reference signal R1 (1), R1 (2). Therefore, this transmission slot number Na
(1), Na (2) are reference signals R1 (1), R1
(2) and the difference between the transmission timings T (1) and T (2). Thereby, in the case of the configuration of FIG.
(1), T (2) are reference signals R1 (1), R1 (2)
Is notified to each of the base stations CS (1) and CS (2).

The transmission slot numbers Na (1) and Na (2) sent to the respective base stations CS (1) and CS (2) are received by the transmission / reception unit 14 and supplied to the superframe transmission unit 13. The super frame transmitting unit 13 also has
The slot number allocating unit 12 supplies the slot number N. Thereby, when the slot number N matches the transmission slot numbers Na (1) and Na (2), the BCCH of the super frame is transmitted.

As a result, in the base station CS (1), FIG.
As shown in (g), the BCCH is transmitted at the slot position of slot number 8. In the base station CS (2), as shown in FIG. 5 (h), the BCCH is transmitted at the slot position of the slot number 11. Below, 500ms
SCCH and PCH are sequentially transmitted in the cycle of (1).

According to this embodiment described in detail above, the following effects can be obtained.

(1) The exchange SW sets the superframe transmission timings T of the respective base stations CS so as not to overlap each other, and notifies the respective base stations CS of the transmission timing T. Even if it increases, the superframe transmission timing T of each base station CS can be prevented from overlapping.

(2) When notifying the transmission timing T to each base station CS, the base station CS transmits a reference signal R1 to the exchange SW, and notifies the difference between the reference signal R1 and the transmission timing T. So that each base station CS
The received notification information can be used as it is as the transmission slot position information.

FIG. 6 is a block diagram showing the configuration of the second embodiment of the present invention.

In the following description, a unique protocol modified so that the Q channel can be sent from the exchange SW to each base station CS in the ISDN layer 1 is used for communication between the exchange SW and each base station CS. Description will be made assuming that communication is performed.

In the above embodiment, the case where the reference timing for transmitting the superframe is independently set for each base station CS has been described. On the other hand, in this embodiment, the reference timing of all the base stations CS is
W is commonly set.

In the above embodiment, the case where the exchange SW manages the superframe transmission timing T of each base station CS has been described. On the other hand, in this embodiment, each base station CS manages its superframe transmission timing T.

That is, in FIG. 6, the base station CS
Transmission slot candidate output unit 31, slot number allocation unit 32, superframe transmission unit 33, transmission / reception unit 34
Having. On the other hand, the exchange SW includes a transmission timing setting unit 41, a reference signal generation unit 42, and a transmission / reception unit 43.

Here, the transmission slot candidate output section 31 of the base station CS outputs one or a plurality of slot candidates capable of transmitting a superframe. This candidate is represented, for example, by a slot number NA.

The slot number allocating unit 32 includes a switch SW
The number N is assigned to each slot with reference to the reference signal R2 sent from.

The superframe sending section 33 compares the slot number N allocated by the slot number allocating section 32 with the transmission slot number Na sent from the exchange SW, and starts sending the superframe when the two match. I do.

The transmission / reception section 34 sends the transmission slot candidate number NA output from the transmission slot candidate output section 31 to the exchange SW, and receives the reference signal R2 and the transmission slot number Na sent from the exchange SW, These are supplied to a slot number allocating unit 32 and a super frame transmitting unit 33, respectively.

Transmission timing setting section 41 of exchange SW
Selects the transmission slot number Na from the transmission slot candidate numbers NA sent from each base station CS so that the superframe transmission timing of each base station CS does not overlap.

The reference signal generation circuit 42 generates a reference signal R as a reference when each base station CS transmits a superframe.
2 is output.

The transmission / reception unit 43 receives the slot number NA sent from each base station CS and supplies this to the transmission timing setting unit 41. In addition, this transmitting / receiving unit 43
While transmitting the transmission slot number Na selected by the transmission timing setting unit 41 to the corresponding base station CS,
The reference signal R2 output from the reference signal generator 42 is transmitted to all base stations CS.

The operation of the above configuration will be described with reference to FIG.

In the following description, base station CS
It is assumed that there are two base stations CS (1) and CS (2).

The transmission slot candidate numbers NA (1) and NA (2) output from the transmission slot candidate output section 31 of each of the base stations CS (1) and CS (2) are transmitted from the transmission / reception section 34 to the IS
The data is transmitted to the exchange SW via the DN interface.
In this case, the transmission slot candidate numbers NA (1), NA
(2) is transmitted using the D channel.

The transmission slot candidate numbers NA (1) and NA (2) sent to the exchange SW are received by the transmission / reception section 43 and supplied to the transmission timing setting section 41. Thereby, each transmission slot candidate number NA is set so that the superframe transmission timing of each base station CS does not overlap.
Transmission slot numbers Na (1) and Na (2) are appropriately selected from (1) and NA (2).

For example, assume that the transmission slot candidate numbers NA sent from the base station CS (1) are 8, 9, and 10, and the transmission slot candidate numbers N sent from the base station CS (2).
Assuming that A is 9, 10, and 11, slot number 8 is selected for base station CS (1), and slot number 11 is selected for base station CS (2). As a result, the transmission timings T (1) and T (2) of the base stations CS (1) and CS (2) are set so as not to overlap each other.

The transmission slot numbers Na (1) and Na (2) selected by the transmission timing setting section 41 are
3 is transmitted to the corresponding base stations CS (1) and CS (2) via the ISDN interface. In this case, the slot numbers Na (1) and Na (2) are transmitted using the D channel.

In parallel with this, the reference signal R2 (see FIG. 7 (a)) output from the reference signal generator 42 is also transmitted from the transmitter / receiver 43 to all the base stations CS (1), CS (1), CS (1), CS (1) Sent to (2). in this case,
This reference signal R2 is obtained by the above-mentioned unique protocol.
It is transmitted using the Q channel.

The reference signal R 2 sent to each of the base stations CS (1) and CS (2) is received by the transmitting / receiving section 34 and supplied to the slot number allocating section 32. As a result, FIG.
As shown in (1), a number N is assigned to each slot based on the reference signal R2. This slot number N
It is supplied to the super frame sending unit 33.

On the other hand, the slot numbers Na (1) and Na (2) sent to each of the base stations CS (1) and CS (2) are received by the transmission / reception section 34 and supplied to the superframe transmission section 33. . Thereby, slot numbers Na (1), Na
When the slot number N matches (2), the BCCH of the superframe is transmitted.

FIGS. 7C and 7D show the transmission of the BCCH in the base stations CS (1) and CS (2), respectively. As shown, the base station CS (1) transmits the BCCH at the slot position of slot number 8, and the base station CS (2) transmits the BCCH at the slot position of slot number 11. Thereafter, SCCH and PCH are transmitted at a period of 500 ms.

According to this embodiment described in detail above, the following effects can be obtained.

(1) First, also in this embodiment, the exchange SW sets the superframe transmission timing T of each base station CS and notifies this to each base station CS. Even if it increases, the superframe transmission timing T can be prevented from overlapping.

(2) In addition, the exchange SW from each base station CS
, And the switch SW sets the superframe transmission timing T of each base station CS based on the transmission slot candidate. Therefore, each base station CS can manage the superframe transmission timing T. The advantage that it can be obtained is obtained.

(3) Further, since the reference timing of all the base stations CS is commonly set in the exchange SW, there is an advantage that it is not necessary for each base station CS to set the reference timing.

Although the two embodiments of the present invention have been described in detail, the present invention is not limited to the above-described embodiments, and may be modified as follows. In the following description, the wired interface connecting the exchange SW and each base station CS is not limited to the above-described ISDN interface or the like.

(1) First, in the first and second embodiments, the case where the period of the reference signal (R1, R2) coincides with the transmission period of the superframe has been described. However, in the present invention, these do not have to match.

FIG. 8 shows an example. The illustrated example shows a case where the period of the reference signal is 1.5 s and the transmission period of the superframe is 0.9 s. The superframe has one BCCH, one SCCH, and four PCHs.
1 to PCH4. The interval between each channel is set to 150 ms.

In this case, the position of the reference signal does not always coincide with the position of the BCCH, but coincides with any of the transmission timings of the LCCH. The advantage is that the structure of the superframe and the transmission timing T can be changed even if the period of the reference signal is determined to be 1.5 s.

(2) In the first embodiment, the case where the reference signal R1 is transmitted to the exchange SW and the transmission slot number Na is obtained by the exchange SW has been described. However, according to the present invention, the superframe transmission timing T may be directly transmitted to each base station CS, and each base station CS may obtain the transmission slot number Na.

(3) In the above description, in the configuration in which the reference timing of all the base stations CS is commonly set in the exchange SW as in the second embodiment, the superframe transmission timing T is set to the base station. The case of management by CS has been described.

[0083]

(4) In the above description, as in the first embodiment, in the configuration in which the reference timing is set independently for each base station CS, the exchange SW is connected to each base station CS.
Has been described.

However, according to the present invention, as in the second embodiment, the reference timings of all
In a configuration in which W is commonly set, the switch SW may manage the superframe transmission timing T of each base station CS.

(5) In the above description, the case where the superframe transmission timing T of each base station CS is set by the exchange SW has been described. However, in the present invention, the setting may be made in a portion other than the exchange SW.

(6) In addition, it goes without saying that the present invention can be variously modified and implemented without departing from the scope of the invention.

[0088]

The superframe of the present invention as described above
According to the transmission timing specification device, even if the number of base stations increases,
Superframe transmission timing at the time of transmission from the base station
To prevent overlapping (time slots).
Can be. Also, in the present invention, transmission of a superframe is performed.
Selection of the slot number that defines the time slot
Since the coordination between the station and the exchange control means
Exchange control means, where
No, it is small in terms of hardware, but it is a base station
It is possible to flexibly cope with an increase in the number.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a first embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a digital cordless telephone system.

FIG. 3 is a diagram for explaining a 4-channel multiplexing TDMA / TDD system.

FIG. 4 is a diagram illustrating a configuration of a superframe.

FIG. 5 is a timing chart for explaining the operation of FIG. 1;

FIG. 6 is a block diagram showing a configuration of a second embodiment of the present invention.

FIG. 7 is a timing chart for explaining the operation of FIG. 5;

FIG. 8 is a diagram for explaining a third embodiment of the present invention.

[Explanation of symbols]

PS: mobile station, CS: base station, SW: exchange, 11, 12
1, 42: Reference signal generator, 13, 33: Super frame transmitter, 14, 25, 34, 43: Transmitter / receiver, 2
2, 41: transmission timing setting section, 121, 23, 32
... Slot number allocating section, 24 ... Transmission slot number detecting section, 31 ... Sending slot candidate output section.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int. Cl. ⁷ , DB name) H04Q ^7/ 00-7/36 H04B ⁷ /24-7/26

Claims (1)

(57) [Claims] 1. An exchange control means, comprising:
From multiple base stations connected to
Superframe of cordless telephone system that sends out
In the transmission timing designating device, each of the plurality of base stations is controlled by the exchange control means to transmit a superframe.
Used as the basis for selecting slot numbers to specify
Base station side reference signal or transmission slot candidate number generated
Above, this base station side reference signal or transmission slot candidate number
Number requesting means for transmitting to the exchange control means
And the slot number notified from the exchange control means.
The super frame is transmitted at the corresponding timing.
Transmission timing control unit for controlling the transmission timing
Sending a superframe under the control of the
An output unit, and the base station-side reference signal or transmission from the plurality of base stations.
The switching control means for receiving the slot candidate number includes a switching signal which is a reference signal generated in the switching control means.
An exchange-side reference signal generating means for generating and outputting a reference signal;
Slot number selecting means for selecting the slot number.
Send at least this slot number to the corresponding base station.
And a time slot notifying means output, the slot number selecting means, said switching control means base
When receiving the station-side reference signal, the plurality of base stations
Time system according to the phase of the base station side reference signal transmitted from
From the serial numbers generated in the sequence, the switching-side reference signal
The corresponding number specified at the different timings above
Output slot number, while sending slot candidate number
If the received slot number is
A different number for each base station from
Characterized in that the connection between the exchange control means and the base station,
ISDN interface for sending time slot notification
A superframe transmission timing designation device, characterized in that: