DE4332999C2 - Method and device for generating a system file in base stations of a multi-cellular, wireless telephone system - Google Patents

Description

The invention is based on a method and a device for creating a system clock in base stations of a multi-cellular, wireless remote speech system according to the in the preamble of claim 1 or according to the features specified in the preamble of claim 6.

From EP 0 226 610 B1 basic systems of wireless are known Telephone systems to a communication system, in particular a private branch exchange. The basic system points a switching technology and possibly a radio technology Part on. The basic system is over several connecting lines connected to the communication system. Here is for each the wireless, d. H. via a radio link to the basic system connected communication terminal - in the professional world as Cordless phone known - a separate connection between the Communication system and the wireless telephone system featured see.

Such multi-cellular, wireless telephone systems are over weighing according to the ETS standard (European Telecommunication Standard) ETS 300 175, Parts 1 to 9, "Digital European Cordless Telecommunications "(DECT), May 1992, realized. According to this The standard is the formation of transmission time slots and de integration into transmissions designed for a radio connection frame and superframe by one in the base stations formed system clock controlled.  

The system clock must meet the following requirements in accordance with the DECT standard meet gene:

• - The information flow controlled by means of the system clock may have a maximum wander of 5 ppm on the radio side be (see Part 2, Chapter 4.2.2),
• - The system clock with a frequency of 1152 kHz may be a ma ximal frequency offset of +/- 50 kHz (see part 2, Cape. 4.1.2) and
• - the jitter between the first bit and any fol of a time slot must not exceed 100 ns ten (see Part 2, Chapter 4.2.4).

These requirements are met by highly accurate clock generators the base stations can be fulfilled. This means a significant one circuitry expenditure for the realization of Taktge generators in the base stations.

The object underlying the invention is that Effort to implement a clock generator in the Base stations taking into account the requirements to be met to reduce changes. The task is based on a Method or of a device according to the features of the preamble of Pa Tent claim 1 and claim 6 solved by their respective features specified in the characterizing part.

Particular embodiments of the invention are the subject of subclaims.

The essential aspect of the method according to the invention is there rin to see that the educated in the communication system, high accurate communication system clock using the transmission tech nik to the base stations - together with the information mations - and on them the system clock generator of the base station tion is synchronized. Here the system clock generator be synchronizable. This is advantageous through a Phase-locked loop designed system clock generator causes - Claim 4. The system clock formed in the base stations controls the formation of time slots, frames and  the superframe, which is used for a subsequent radio technical over to be compiled according to DECT standards - An saying 2. According to this DECT standard, an overframe is through 16 frames are formed, each frame having 24 time slots, i. H. 24th includes radio transmission channels.

In the communication system, the highly precise communication system master clock a transmission clock with a frequency of 8 kHz and are derived with the derived transmission clock Transmission units synchronized in the communication system, d. H. the transfer clock oscillators synchronized. In the Ba sis stations is made up of the transmitted transmission signals of the Transfer clock derived from 8 kHz and with this the Sy Master clock generator synchronized. The synchronized system clock has a frequency of 1152 kHz and a time slot comprises 480 bits. Under these conditions, the beginning every third time slot with the beginning of every tenth over Carrier clock compared in terms of their phase and in Depending on the comparison result, the frequency of the System clock generator controlled in the base station, i. H. so long decreased or increased until approximately a phase synchro is achieved - claim 3. Regulating the frequency of the System clock generator is advantageous through a digital or an analog phase locked loop.

According to a further advantageous embodiment of the inventions The method according to the invention is based on the transmission units Time separation transmission method implemented - claim 5. The use of the time separation transmission method allows the use of highly integrated circuit technology and thus a particularly economical realization of a transfer Ness.  

Are particularly advantageous in an arrangement for generating a System clock in base stations of a multi-cellular, wire loose telephone system the base stations each over at least a connection line with a communication system connected, taking digital information between the communica tion system and the base stations through in one transmission clocked clocked, in each case in the communication system and in the Ba transmission stations arranged over stations carrier signals are transmitted, and the communication system and the base stations are designed such that the im Communication system generated communication system clock the Transmission clock of the communication system is derived, so as with the derived transmission clock, the one with the respective Base stations connected to the commu nication system synchronized and the communication system clocked transmission signals to the base stations are transmitted, and in the base stations with the in each case base unit's transmission unit from the over transmission signals derived transmission clock by syn Chronizing signals synchronizable, forming the system clock System clock generator is synchronized - claim 6. By this arrangement is taking into account a substantial in integration of these components into integrated circuits particularly economical connection of multi-cellular, wire loose telephone systems to a communication system bar.

The method according to the invention is described below using a Block diagram and a signal flow diagram closer he purifies. Show  

Fig. 1 in a block diagram of a wireless system Telefunkensy and

Fig. 2 in a signal flow diagram, a transmission clock and a time slot signal sequence.

Fig. 1 is a block diagram of a communications system KS to which an example of a base station BS is connected via connection lines 3, the illustrated 8 VL. The remaining five connecting lines VL lead to further base stations BS, not shown and indicated by dots. The connecting lines VL are routed in the communication system KS to a transmission unit OCTAT arranged in a base station connection module SLMC. In the transmission unit OCTAT, a transmission circuit UP1-UP8 is provided for each incoming connection line VL. Through these transmission circuits UP1-UP8 a UP interface acting according to the time-separated transmission method is realized. The bidirectional information transmission via the UP interface UP is effected by information bursts with a transmission speed of 384 kB / s.

The information received or the information to be sent is included With the help of a multiplex-demultiplex device MD to an information mation current of 2048 kB / s combined and sent to an ISDN oriented, internal system bus interface IOM controlled. This system bus interface is similarly reali based, internal ISDN-oriented system bus interface IOM ei ner arranged in the base station connection module SLMC pheries control switched ELIC. The system bus interface IOM is in the ELIC peripheral control on a D-channel control DA realized with the help of the allocation or blocking the signaling channels in the connecting lines VL be will work. The news channels, i. H. the B channels are on switched a switching unit EPIC. In this mediation EPIC is a time slot controlled switching matrix in the implemented. With the help of this switching matrix there are 64 messages 64 kB / s channels can be switched. This means that with help this switching matrix 32 wireless to the base stations BS closed communication terminals KE can be switched bidirectionally are. The switching unit EPIC also has three bi directional PCM-oriented bus interfaces PCM1. . . 3 on where for the first bus interface PCM1 with others, not shown provided facilities of the communication system (KS) connected is. The second and third PCM-oriented bus interface  PCM2, 3 is each with a delta modulation or demodula tion device ADPCM1, 2 connected, with a delta Modulation or demodulation device ADPCM1, 2 16 each bidirectional message channels B according to the delta modulation or demodulation processes are editable. With the help of Delta modulation or demodulation device ADPCM1, 2 are the transmission speeds of the message channels B from 64 kB / s can be reduced to 32 or 16 kB / s, for example. By this measure can increase the number of connecting lines VL between the communication system KS and the base stations BS be significantly reduced.

With the help of the D-channel control DA, those in the D-channels signaling information contained or to be inserted - e.g. B. in channel 31 of the 64kB / s channels, demultiplexing Bitstream - read or inserted and sent to a signal management control SIS directed or taken over by this. With With the help of the signaling control SIS the signalisie information through an HDLC transmission procedure an interface control SST to other, not shown Controls of the communication system KS transmitted. The Si Signaling channel control DA is in terms of control the signaling and message channels according to the German patent application P 41 41 493.4 trained. Here the signaling channels are temporarily the UP interfaces UP assigned or blocked.

For the exemplary embodiment it is assumed that in the communication tion system (KS) with the help of a, not shown, hochge accurate clock system communication signals kts formed with a frequency of 8 kHz and to the base sta tion connection modules SLMC are distributed. In the base station final module SLMC, the communication system clock signals kts to synchronize the message and signaling information  mations processing facilities ELIC, ADPCM 1, 2 used. The communication system clock signals kts are from the switch ELIC unit via the ISDN-oriented internal system bus Interface IOM transmitted to the transmission unit OCTAT - indicated by dashed lines. In the transference unit OCTAT using the communication system clock kts the transmission circuits forming the transmission signals ui UP1. . . 8 synchronized, i. H. from the communication system clocksi gnalen kts the transmission clock ut of 384 kb / s synchroni siert. This synchronization can be done, for example, by a digital or analog phase locked loop PR can be effected.

The three connecting lines VL are in the base station BS each to a line connection unit DSAC1. . . 3 led. Everyone this line connection units DSAC1. . . 3 has one according to the Transmission circuit UP1. . . 8 realized transmission circuit UP on, through which a transmission according to the time separation Transmission process is effected. Furthermore, in the Transmission circuits UP from the incoming transmission sinalen ui the transmission clock ut with a frequency of 8kHz derived. This transmission clock ut approximately has the same accuracy and stability as that of the highly exact communication system clock controlled transmission clock ut on.

The transmission circuit UP is an ISDN orien ISDN system that realizes internal system interface IOM oriented interface circuit ISM connected. This ISDN oriented internal system interface IOM points in contrast to the system bus interface IOM in the base station connection module SLMC only two message or B channels and one Signa channel and another system-internal informa tion channel and additionally a clock line for transmission of the transmission clock signals ut. The ISM interface module  ISM is also ver with a signaling control SIS bound. With the help of this signaling control SIS Signaling information of the signaling channels or D- Receive or ge channels according to the HDLC transmission method sends and for transmission via a processor interface set up PST and a local bus LB to a controller BST prepares d. H. for transmission to the data, address and Control lines of the local bus LB adapted. This local Bus LB is also with a read memory ROM and one Read-write memory RAM connected. Here are in the write le memory RAM essentially the non-resistant informa tions and in the read-only memory ROM which monitors the base station BS appropriate and coordinating programs.

The ISDN-oriented, internal system interfaces IOME the Line connection units DSAC1. . . 3 are connected to a burst module performed, with the at least one of the three clock lines Transmission clock ut additionally to a system clock generator BTG the base station BS is transmitted - by dashed line Li not shown. In the system clock generator BTG the Sy system clock T for a time slot counter SLC, a frame counter FC and an overframe counter MFC formed. With the help of Time slot counter SLC, the frame counter FC and the Überrah time counter clocks zst, frame clocks and Generated superframe clocks and with these time slots, frames and Frame according to ETS standard 300 175, Digital European Cordless Telecommunication (DECT) formed.

According to the invention, the system clock generator BTG of the base station BS is synchronized with the aid of one of the three highly precise transmission clocks. One of the three transmission clocks ut is selected for the synchronization - z. B. from the Lei line connection unit DSAC1 - and in its failure or malfunction ut switched to one of the remaining transmission clocks. For the synchronization of the system clocks T formed in the system clock generator BTG with a frequency of 1152 kHz with the highly precise transmission clocks ut with a frequency of 8 kHz, the beginning of every tenth transmission clock ut and the beginning of every third time slot clock zst formed with the help of the time slot counter SLC are used, ie their signal edges are compared in terms of their phase position - see FIG. 2 for this purpose . The system clock generator BTG, which is implemented, for example, by a digital or analog phase-locked loop, is synchronized as a function of the phase comparison results found. On the voltage oscillators or clock oscillators used in these phase-locked loops, controlled by impingement or impulse suppression, the requirements for accuracy and stability are significantly lower than for clock oscillators that are not synchronized by highly precise clocks, in the exemplary embodiment the transmission signal averaged. Consequently, the circuitry outlay for the system clock generators BTG to be implemented in the base stations BS can be significantly reduced, taking into account the considerable requirements with regard to accuracy and stability.

With the help of the clocks tv formed in the counters SLC, FC, MFC are processed in a processing unit VEE that is connected to the ISDN oriented, internal system interfaces IOME is connected, the messages or information in the appropriate frame inserted or removed and transmitted to a radio module FM or received by it. Arranged in a in the burst module BM th clock unit TE, which is connected to the system clock generator BTG that is, both additional burst module-internal clocks are generated det, as well as the required clocks according to the DECT standard formed for the radio module FM and transmitted to it.  

With the help of the FM radio module, the messages and Signa lization information according to the DECT standard with a Fre frequency of 1800 MHz. According to the DECT standard, 12 include bidirectional 64kB / s message channels Lich the associated signaling information wirelessly be transmitted. This means that 12 Communication terminals KE, d. H. 12 wireless phones, wireless on are closable.

Claims (6)

1. A method for generating a system clock (T) in base stations (BS) of a multi-cellular, wireless telephone system in which the base stations (BS) are each connected via at least one connecting line (VL) to a communication system (KS), with digital information between the communication system (KS) and the base stations (BS) formed by transmission units (OCTAT, DSAC1... 3) formed in a transmission clock (ut), respectively in the communication system (KS) and in the base stations (BS), transmission signals (ui ) are transmitted, characterized in that
that the communication clock (ui) of the communication system (KS) is derived from the communication system clock (kts) generated in the communication system (KS),
that with the derived transmission clock (ui) the transmission units (OCTAT) of the communication system (KS) connected to the respective base stations (BS) are synchronized and the communication system clock-clocked transmission signals (ui) are transmitted to the base stations (BS),
that in the base stations (BS) with the transmission clock (ut) derived from the transmission signals (ui) in the respective transmission units (DSAC1... 3) of the base stations, a system clock (T) forming system clock generator (BTG) that can be synchronized by synchronization signals is synchronized. 2. The method according to claim 1, characterized, that in the communication system (KS) the system clock (kts) regards Frequency accuracy, wander and jitter according to the ETS standard 300 175 "Digital European Cordless Telecommunications (DECT) "is formed.   3. The method according to claim 2, characterized, that the transmission clock (ut) a frequency of 8 kHz and the System clock (T) of a base station (BS) a frequency of 1152 kHz, each representing a transmission channel end time slot (TS) includes 480 bits that the beginning of each third time slot clock (zst) at the beginning of every tenth Transfer clock (ui) is compared in terms of phase and that depending on the phase comparison result Frequency of the system clock (bst) of the base stations (BS) controlled becomes. 4. The method according to any one of the preceding claims, characterized, that the system clock generator (BTG) in the base station (BS) realized by an analog or digital phase locked loop is. 5. The method according to any one of the preceding claims, characterized, that the transmission units (OCTAT, DSAC1... 3) in the communication system (KS) and in the base stations (BS) according to the times separation layer transmission methods are realized. 6. Arrangement for generating a system clock (T) in base sta tions (BS) of a multi-cellular, wireless telephone system, in which the base stations (BS) each have at least one Connection line (VL) with a communication system (KS) are connected, digital information between the com communication system (KS) and the base stations (BS) through in one Transmission clock (ut) clocked, each in the communication system (KS) and in the base stations (BS) arranged transmissions  transmission units (OCTAT, DSAC1... 3) (ui) are transmitted, characterized, that the communication system (KS) and the base stations (BS) are designed such that the in the communication system (KS) generated communication system clock (kts) of the transmission clock (ut) of the communication system (KS) is derived with the derived transmission gungstakt (ut) ver with the respective base stations (BS) bound transmission units (OCTAT) of the communication system (KS) synchronized and communication system clocked transmission signals (ui) the base stations (BS) are transmitted that in the Ba stations (BS) with the one in the respective transmission unit (DSAC1... 3) of the base stations (BS) derived from the transmission signals (ui) Transmission clock (ut) on by synchronizing signals synchroni adjustable system clock generator forming the system clock (T) (BTG) is synchronized.