DE19946067A1 - Wireless data transmission system for cordless telecommunications has data processor which modulates carrier frequency, varies carrier frequency and transmits data in time frames - Google Patents

Abstract

The system includes a base station (1) and a handset (5). The base station and the handset comprise respective a respective data processing device which modulates or demodulates a carrier frequency with the data, varies the carrier frequency after a predetermined period of time, and transmits the data in time frames having less than 24 time slots. The data in the time slots are transmitted using time division and frequency division multiplexing. Data are transmitted in a frequency band between 902 and 928 MHz or 2400 to 2483.5 MHz or 5725 to 5850 MHz. The time frame may have a duration of 10 ms. Independent claims are included for a terminal and a method for wireless transmission of data.

Description

The invention relates to a system, a device and a method for wireless transmission carrying data.

For some years now, DECT Default. This is explained in more detail in the description of the exemplary embodiment. The us Legislature has regulations through Federal Communications Commission Title 47 Part 15 met, according to which air interfaces work for wireless data transmission systems have to. The transmission of data according to the DECT standard meets this requirement not changes.

The invention has for its object a system, corresponding terminals for a to provide such a system and method for wireless data transmission that the standards of US legislation while maintaining the largest possible The scope of the standardization of the DECT standard is sufficient. The task is performed by the Features of claim 1 solved. The essence of the invention is a data about to provide a support system according to the DECT standard, in which every time frame less time slots than are provided according to the DECT standard and a Frequency hopping is applied.

Further advantageous embodiments of the invention result from the subclaims.

Additional features and details of the invention will become apparent from the description an embodiment with reference to the drawing. Show it:

Fig. 1 shows an inventive arrangement for wireless transmission of data,

Fig. 2 shows the structure of a time frame and a time slot according to the DECT standard, and

Fig. 3 shows the structure of a time frame and a time slot according to the invention.

A system for the wireless transmission of data has a base station 1 which is connected to the fixed telephone network 3 by means of a data transmission line 2 . The base station 1 has a high-frequency module with which data can be sent or received via an antenna 4 . In addition to the base station 1 , cordless handsets 5 with antennas 6 are provided, which also have a high-frequency module. The transmission of data between the base station 1 and the handheld devices 5 follows by frequency-modulated radio transmission.

Data transmission according to the DECT standard is first described below with reference to FIG. 2. In Europe, the European Telecommunications Standard Institute (ETSI) adopted the first European standard for wireless communication, namely Digital Enhanced Cordless Telecommunications (DECT). The DECT standard standardizes communication in a microcellular, digital, cordless data transmission system of the type described at the beginning. The DECT standard permits communication with a maximum of 120 handheld devices 5 . The transmission takes place on ten carrier frequencies at frequencies of 1.88 GHz + n.1.728 MHz, where n = 0. , ., 9. The bandwidth is 1,728 MHz. This is called frequency division multiplexing.

The data are transmitted in time frames 7 , which are usually referred to as frames. A time frame 7 consists of 24 channels, the first 12 channels being used for transmission from base station 1 to handheld devices 5 and the second 12 channels being used for transmission from handheld devices 5 to base station 1 . The duration of a time frame 7 is 10 ms. The duration of a channel, which is referred to as time slot 8 and in technical terms as a slot, is 416.67 µs. 11520 bits are transmitted in a time frame 7 and 480 bits in a time slot, 320 bits of which are voice data and 160 bits of control data or unused data. Within a time frame 7 , 12 time slots 8 are transmitted in succession in a so-called time-multiplexing process, the carrier frequency being able to change from time slot to time slot. The next 12 time slots that follow in time serve, as already mentioned above, for communication from the hand-held devices 5 to the base station 1 .

The structure of a time slot 8 according to the DECT standard is described in more detail below. A time slot 8 has a 16-bit preamble field, which is used for clock recovery, the so-called P field. This is followed by a 16-bit synchronization field, which is used, among other things, to determine the zero point in time and to determine whether it is data from the base station 1 or from a handheld device 5 , the so-called S field. This is followed by a 48-bit control data field, which contains, among other things, data about which base station 1 it is, the so-called A field. This is followed by a 16-bit error check field for performing a so-called cyclic redundancy check, the so-called CRC field. This is followed by a 320 bit voice data field, the so-called B field. This is followed by a 4-bit test field for the B field, the so-called X field. This is followed by a 4-bit field, the so-called Z field, with which it can be determined on the respective receiving side whether there is an overlap in time with another transmitter. This is followed by a 56-bit security field, the so-called G-field. This is used to provide time for the RF module to settle to a new frequency. Especially when using RF modules with slow frequency changes, so-called slow-hopping modules, only every second time slot 8 is used to transmit data to increase the settling time.

A time slot and the associated carrier frequency define a DECT channel. The The carrier frequency is selected in such a way that the signal levels of all are regular Channels are measured and the ones that are most interference free are selected. As long as there is no interference on a channel, the carrier frequency is not changed. Only if it turns out that the currently used channel is on a carrier frequency is transmitted, which is disturbed for a certain period of time, for subsequent ones Transmissions selected an undisturbed carrier frequency.

The following are the legal requirements in the USA for cordless phones networks summarized. These are in Federal Communications Commission Title 47 Part 15 described. First of all, the transmission cannot be in the same frequency range as according to the DECT standard, but in the frequency bands from 902 to 928 MHz, 2400 up to 2483.5 MHz or 5725 to 5850 MHz. With the frequency hopping ver drive, the so-called frequency hopping process, the jump channel  Carrier frequencies of at least 25 kHz or 20 dB of the bandwidth of the jump channel be spaced, the larger of which is to be selected in each case. Every frequency must be on average can be used equally by every transmitter. The hop frequencies must be off a pseudo random list of hopping frequencies can be selected. By doing At least 50 hop channels must be used in the 902 to 928 MHz band 2400 to 2483.5 MHz and 5725 to 5850 MHz bands must have at least 75 jump channels are used. The maximum permissible is in the 902 to 928 MHz band 20 dB bandwidth of the jump channel 500 kHz, in the 2400 to 2483.5 MHz and 5725 to 5850 MHz bands is the maximum permissible 20 dB bandwidth of the jump channels 1 MHz. The assignment of a single frequency is not permitted in the 902 to 928 MHz band more than 0.4 s in a 20 s interval, in the 2400 to 2483.5 MHz and 5725 up to 5850 MHz bands, the average time occupancy of each individual Frequency should not be more than 0.4 s in a 30 s interval. In addition, the The use of beacons, so-called beacons, is not recommended.

The DECT standard therefore does not meet the requirements of the US legislature in some respects. Firstly, the bandwidth of approximately 1.7 MHz used is too large. In addition, the use of beacons is not desired, so that the coordination between base station 1 and handheld devices 5 takes too long during asynchronous operation. In addition, the RF module should settle in the security field G, since no inactive time slots 8 are to be used.

The system and method for wireless transmission according to the invention is described below Data transfer described, with only the changes compared to the DECT standard is received. Otherwise, reference is made to the above description of the DECT standards and referenced to them themselves. The one described below Embodiment applies to the 902 to 928 MHz band. However, it can also be used for other frequency bands permitted by US legislation are used.

As shown in FIG. 3, the time length of a time frame of 10 ms is retained. The number of time slots 8 is reduced to two, namely the time slots with the numbers 0 and 1, with time slot number 0 for the transmission of data from the base station 1 to the handheld devices 5 and time slot number 1 for the reception of data from the handheld devices 5 by the Base station 1 is used. It is generally possible to reduce the number of time slots 8 per time frame 7 to another number less than 24. The amount of data transmitted per time slot is 480 bits, ie a total of 960 bits for time frame 8 . This results in a data transfer rate of 96 kbit / s, whereas the data transfer rate according to the DECT standard is 1.15.2 Mbit / s. A necessary bandwidth of 150 KHz can be determined from the data transmission rate of 96 kbit / s, so that 170 channels can be realized in the specified frequency band, of which only 50 are mandatory according to US legislation. A selection of the least disturbed channels can thus be made.

The data structure of a time slot 8 according to the DECT standard is essentially retained. This applies to the preamble field P, the synchronization field S, the control data field A, the voice data field B and the test field X. The data of the CRC field are used as a multi-purpose field MP (multi purpose) used. The data corresponding to the data area of the Z field, ie between bits 420 and 424, is added to the security field G. The Z-field is not required for frequency hopping since successive time slots 8 are transmitted on different frequencies. The G field according to the invention thus contains 60 bits in contrast to the 56 bits according to the DECT standard. In addition, the temporal length of the G field 10 71 is as long as that according to the DECT standard, since only two time slots 8 are contained in one time frame 7 . The RF modules therefore have a lot more time to tune into the frequency of a new channel, which means that less expensive devices can be used.

The MP field can be used in different ways. Since the use of beacons is not recommended, the connection establishment in asynchronous mode is a time problem when there is an incoming call between base station 1 and handheld devices 5 , as shown above. If only the 16 bits of the S field are used to establish the connection To enable identification of base station 1 and the associated hand-held device 5 , there is a risk that a signal corresponding to the identification signal will be generated approximately every 23 s by noise. If the 16-bit S-field and the 16-bit MP-field are used together for identification, the probability that a certain identification signal is generated by noise is reduced on average to every 17 days. The combination of S-field and MP-field can be used in asynchronous mode to establish a connection for identification. In addition, with an existing speech connection, the MP field can be used for the transmission of speech data, ie user data. It can also be used as a CRC field.

Claims (10)

1. System for wireless data transmission

• a) a base station ( 1 ) for sending and receiving data and
• b) at least one handheld device ( 5 ) for receiving data from the base station ( 1 ) and for sending data to the base station ( 1 ),
• c) the base station ( 1 ) and the at least one handheld device ( 5 ) each having a data processing device,
  • a) which modulates or demodulates the data on a carrier frequency,
  • b) which changes the carrier frequency after a predetermined period of time and
  • c) which transmits the data in time frames which have fewer than 24 time slots,
  • d) wherein the data of the time slots are transmitted in a time division multiplex method and a frequency division multiplex method.

2. System according to claim 1, characterized, that the transmission of data in a frequency band between 902 to 928 MHz, or 2400 to 2483.5 MHz or 5725 to 5850 MHz. 3. System according to claim 1 or 2, characterized in that the predetermined period of time after which the carrier frequency is changed corresponds to an integer multiple of the time length of a time slot ( 8 ) or a time frame ( 7 ). 4. System according to any one of the preceding claims, characterized in that a time frame ( 7 ) has a duration of 10 ms. 5. System according to one of the preceding claims, characterized in that a time slot ( 8 ) has in chronological order:

• a) a 1 G bit preamble field,
• b) a 1 G bit synchronization field,
• c) a 48 bit control data field,
• d) a 1 G bit multi-purpose field,
• e) a 320 bit speech data field,
• f) a 4 bit test field and
• g) a GO bit security field.

6. System according to claim 5, characterized in that two time slots ( 8 ) are contained in a time frame ( 7 ). 7. System according to claim 5 or 6, characterized in that the data of the synchronization field and that of the multipurpose field are used together for synchronization between the base station ( 1 ) and the at least one handheld device ( 5 ). 8. System according to claim 5, characterized, that the data of the multipurpose field are used for the transmission of user data.   9. Terminal ( 5 ) for the wireless transmission of data with

• a) a receiving and transmitting part for receiving data from a base station ( 1 ) and for sending data to the base station ( 1 ),
• b) the terminal ( 5 ) each having a data processing device,
  • a) which modulates or demodulates the data on a carrier frequency,
  • b) which changes the carrier frequency after a predetermined period of time and
  • c) which transmits the data in time frames which have fewer than 24 time slots,
  • d) wherein the data of the time slots are transmitted in a time division multiplex method and a frequency division multiplex method.

10. A method for wireless transmission of data comprising the following steps:

• a) Providing a data transmission system with
  • a) a base station ( 1 ) for sending and receiving data and
  • b) at least one handheld device ( 5 ) for receiving data from the base station ( 1 ) and for sending to the base station ( 1 ),
  • c) the base station ( 1 ) and the at least one handheld device ( 5 ) each having a data processing device,
• b) modulating or demodulating the data to a carrier frequency by the data processing device,
• c) change of the carrier frequency after a predetermined period of time by the data processing device,
• d) transmission of the data in time frames ( 7 ), which have fewer than 24 time slots ( 8 ), by the data processing device, the data of the time slots ( 8 ) being transmitted in a time division multiplex method and a frequency division multiplex method become.