DE19827028C2 - Method and device for the wireless transmission of data according to an FSK method, in particular a GFSK method - Google Patents

Description

The present invention relates to an appliance and ice Method for the wireless transmission of data according to a FSK method such as the GFSK method as it used in accordance with the DECT standard, among others.

According to the DECT standard, data is processed according to a GFSK (Gaussian Frequency Shift Keying) method modulated. down Details of the DECT standard are visible, for example to David, Benkner, "Digital Mobile Radio Systems, Taubner Ver lag, Stuttgart, 1996, ISBN 3-519-06181-3. According to the DECT standard data in a frequency range of 1880 up to 1900 MHz (in the extended case up to 1930 MHz) in 120 Du transmit plex channels. The channel spacing is 1728 kHz. It becomes the TDMA access procedure with a frame of 10 ms used. The TDD method is used as a duplex method applies.

However, the present invention applies to all FSK-Ver drive and their derivatives application.

While the amplitude of a Trä Vibration changes by modulating the digital signals is changed, but the frequency remains constant, it is at the frequency shift keying (FSK) exactly swept, d. H. the information is contained in the frequency. The abrupt switching from one frequency to another leads however, to relatively high spectral side bands where is occupied by a high bandwidth by the transmission signal. This behavior can be verified by baseband filtering improve. A frequency filter g (t) is used, which does not a rectangular course, but rather a smoothed one Has history. The smoothing function can, for example  be taken over by a Gaussian low pass. Consequently GFSK modulation will be obtained.

The impulse response h (t) of a Gaussian low pass is:

where B is the 3 dB cutoff frequency. The Gaussian low-pass filter can be switched directly before the modulation input of a VCO. At the modulation input there are pulses that result from the folding of the original rectangular pulses with the impulse response of the Gaussian low pass:

Here erf (x) is the Gaussian error function:

The GFSK transmission filter can be clearly identified by its modulation index ("BT ratio"). In FIG. 6, the impulse response of the transmission filter is indices for different modulation (BT), respectively. It can be seen here that as the modulation indices become smaller, the impulse response becomes wider and thus a "partial response" behavior occurs.

For the application in DECT devices the modulation ver drive GFSK with a nominal modulation index (BT) of 0.5 specifies what ent a frequency swing of 288 kHz speaks. When determining the modulation index is relevant Lich a frequency range from 202 kHz to 403 kHz permeable.  

According to the prior art, the frequency swing is on a fe Most value set, an adaptation is not possible.

DE 196 20 843 A1 describes a method for modulation modulation carrier and a mobile communication system knows, in which the modulation parameter "number of stages" adaptive the respective existing transmission conditions fits that the probability of error largely kon remains constant.

It is therefore an object of the present invention, a poss ability to adapt wireless transmission transfer of data to various environments in accordance with an FSK procedure creating scenarios.

According to the idea of the invention, the frequency swing an FSK procedure, for example the GFSK procedure depending on various parameters.

The above-mentioned task is explained more precisely by the Merk male of claims 1 and 9 solved. Form the subclaims the idea of the invention in a particularly advantageous manner further.

According to the invention is a method for wireless Transmission of data provided according to an FSK procedure. Data is received and the error rate (BER, bit Er ror rate) of the received data. At the same time the field strength (RSSI value) of the received data is measured. It the error rate and the field strength are evaluated. Depending on the evaluation of the error rate and the field strength the frequency swing of the FSK-Ver is then set driving, which is used for wireless transmission of data to optimize the transmission behavior.

The frequency swing can be within a preset Range can be changed.  

The optimization of the transmission behavior can be based on a Table are made showing the reachable range of the transmission plays depending on the set frequency deviation.

In the event that the evaluation has a low field strength and the frequency deviation can result in a low error rate at the same time  to a maximum based on the table mentioned Range can be optimized.

The optimization of the transmission behavior can be based on a second table, which shows the achievable immunity to interference transmission depending on the Fre quenzhub reproduces.

In the event that the evaluation has a high field strength and frequency results in a high error rate at the same time stroke to a maximum based on the second table mentioned Immunity to interference can be optimized.

The transmission can take place according to the DECT standard.

The optimal frequency swing can for a maximum range be chosen smaller than the frequency swing for a maximum Noise immunity.

According to the present invention, a device for wireless transmission of data according to an FSK procedure, as used for example according to the DECT standard, intended. The device has a receiver and a first measuring device for the error rate (BER, bit error rate) of the received data. There is also a second measurement Direction for the field strength while receiving the data intended. An evaluation unit processes the measured Error rate and the measured field strength. A control unit is also provided to the frequency shift of the FSK process rens, which is used for the wireless transmission of data by a Transmitter is used, depending on the measured error rate and the measured field strength to optimize the transfer setting behavior.

Other features and advantages of the present invention from the following exemplary explanation of an embodiment  and referring to the accompanying Drawings can be seen in more detail, in which:

Fig. 1 shows the structure of a device according to the invention for wireless transmission of data according to an FSK Ver drive,

Fig. 2 shows the bit error rate in dependence on the signal to noise ratio (SNR) according to a simulation,

Fig. 3, the bit error rate of a wireless transmission function of the signal-to-noise ratio for a frequency deviation of the interfering signal of 340 kHz,

Fig. 4, the bit error rate in dependence on the signal-to-noise ratio for a frequency deviation of the interfering signal of 288 kHz,

FIGS. 5a to 5d, the various spectra of GFSK signals which have been spent for the measurement in accordance with FIGS. 2 to 4 ver, and

Fig. 6 shows the impulse response g (t) of a GFSK filter.

The present invention is generally found in FSK processes Application and is for example based on a GFSK procedure rens described.

According to the present invention, the appearance is made useful that depending on the modulation set dex (BT value) of an FSK procedure, for example the GFSK Procedure a different system behavior of wireless Sen transmission, for example, with regard to the limit sensitivity (range) or immunity. Becomes the greatest possible range for the transmission strives, according to the invention differs for that choosing frequency shift from the frequency swing one to maximum  Immunity optimized system. Therefore, according to the before lying invention after evaluation of the bit error rate (BER, Bit Error Rate) and the corresponding RSSI (radio signal Strength Indicator, reception field strength) values by an ent speaking setting of the frequency swing (corresponding to a Modulation index) an adaptation of the system to different Scenarios.

As can be seen in FIG. 1, digitally modulated signals can be received by an antenna 1 and sent to a receiver (receiver) 3 . The receiver 3 transmits the received data (RX data) 7 on the one hand and the RSSI value 8 to an evaluation unit 6 on the other hand. More precisely, the receiver 3 transmits the received data 7 and the RSSI value 8 to a control unit 13 in the evaluation unit 6 .

In addition to the control unit 13 , the evaluation unit 6 has a first table 12 and a second table 14, each of which is connected to the control unit 13 . The control unit 13 in the evaluation unit 6 , on the one hand, controls a local oscillator (synthesizer) 4 , which is connected to the receiver (re ceiver) 3 and a transmitter (transmitter) 5 of the mobile radio device 16 . On the other hand, the control unit 13 of the evaluation unit 6 controls the frequency deviation used by the transmitter 5. The evaluation unit 6 also transmits data 11 to be transmitted to the transmitter 5 , which transmits this data (TX data) 11 with that specified by the control unit 13 Frequency deviation 10 modulated to the frequency of the local oscillator (synthesizer) 4 and then passed on to an antenna 2 for transmission via a wireless transmission path 15 .

The control unit 13 in the evaluation unit 6 thus receives the received data 7 and the RSSI value 8 from the receiver 3 . The bit error rate of the received data 7 and the received field strength (RSSI value) measured by the receiver 3 are evaluated in the control unit 13 , so that the following scenarios can be distinguished:

Case a)

No or little influence by interference signals: The received data 7 have small bit error rates with a low reception field strength at the same time. In this case, the control unit 13 can control the frequency stroke of the transmitter 5 for maximum range.

Case b)

Interference from other signals, such as DECT signals: In this case, relatively high bit error rates occur at relatively high reception field strengths. In this case, the control unit 13 of the evaluation unit 6 controls the frequency swing of the transmitter 5 for maximum immunity to interference.

To optimize the system for maximum range or maximum immunity to interference, the first table 12 and the second table 14 are provided in the evaluation unit 6 . In the first table 12, the maximum achievable range of the wireless transmission 15 is specified as a function of the frequency range that can be selected within a permitted range. The second table 14 shows the maximum immunity to interference as a function of the frequency swing.

Tables 12 and 14 are created, for example, before the actual transmission by analyzing the system behavior of the wireless transmission 15 by simulations with different frequency sweeps. In FIG. 2, the bit error rate is a function of the signal-to-noise ratio calculated. The curves shown in FIG. 2 represent the following key data:
Frequency shift of 202 kHz: lower limit of the permitted standard,
Frequency swing of 288 kHz: nominal value,
Frequency sweep of 340 kHz: frequency sweep, as is fixed in some devices according to the prior art,
Frequency swing of 403 kHz: Upper permitted limit of the DECT standard.

By evaluating the diagram shown in Fig. 2, one comes to the conclusion that in a system optimized for maximum range, a frequency deviation of 340 kHz must be set, which corresponds to the above-mentioned case a).

Further simulations characterize the immunity to interference of a DECT connection (case b)). According to the calculations shown in FIGS. 3 and 4, it can be seen that in this scenario the coexistence of different systems must still be considered. In the case of an interference signal with a 340 kHz frequency swing (e.g. neighboring conventional DECT systems), the optimal frequency swing, as is to be used in the present invention, is also 340 kHz (see FIG. 3). According to the present invention, the nominal frequency deviation of 288 kHz is set in the case of co-channel interference in all systems ( FIG. 4).

FIGS. 5a to 5d show the test signals used in the simulations.

According to the present invention can thus by evaluation the bit error rate and the corresponding RSSI value Corresponding setting of the frequency swing of an FSK over adaptation of the system to different scenarios be made.

Claims (16)

1. Method for the wireless transmission of data in accordance with an FSK method,
comprising the following steps:

• - reception ( 1 , 3 ) of data,
• Measurement ( 6 ) of the error rate of the received data,
• - measurement ( 3 ) of the field strength ( 8 ) upon receipt of the data,
• - Evaluation ( 6 ) of the error rate and the field strength,
• - Setting ( 5 , 6 , 10 ) the frequency swing of the FSK method that is used for wireless transmission ( 15 ) of the data, depending on the evaluation ( 12 ) of the error rate and the field strength in order to optimize the transmission behavior ( 13 ).

2. The method according to claim 1, characterized, that the frequency swing within a preset range is changed. 3. The method according to any one of the preceding claims, characterized in that the optimization of the transmission behavior takes place on the basis of a table (12) which reflects the achievable range of the transmission ( 15 ) as a function of the set frequency swing. 4. The method according to claim 3, characterized in that in the event that the evaluation ( 6 ) strengthens a small field and at the same time results in a low error rate, the frequency deviation is optimized to a maximum range using the table (12) ( 13 ) becomes. 5. The method according to any one of the preceding claims, characterized in that the optimization of the transmission behavior takes place on the basis of a second table (14) which reflects the achievable interference sensitivity of the transmission ( 15 ) depending on the frequency swing set. 6. The method according to claim 5, characterized in that in the event that the evaluation ( 6 ) results in a high field strength and at the same time a high error rate, the frequency deviation is optimized using the second table (14) for maximum interference immunity ( 13 ) becomes. 7. The method according to any one of the preceding claims, characterized in that the transmission ( 15 ) takes place according to the DECT standard. 8. The method according to any one of the preceding claims, characterized, that the optimal frequency swing for a maximum range ge ringer is selected as the frequency swing for a maximum Noise immunity. 9. Device for the wireless transmission of data according to an FSK procedure,
comprising:
a receiver ( 3 ),
a measuring device ( 6 ) for the error rate of received data,
a second measuring device ( 3 ) for the field strength ( 8 ) when receiving the data,
an evaluation unit ( 6 ) for the measured error rate and the measured field strength,
a control unit ( 13 ) for setting the frequency swing of the FSK method, which is used for wireless transmission ( 15 ) of the data by a transmitter ( 5 ), depending on the measured error rate and the measured field strength, in order to optimize the transmission behavior. 10. Apparatus according to claim 9, characterized, that the frequency swing within a preset range is changeable. 11. Device according to one of claims 9 or 10, characterized in that in order to optimize the transmission behavior in the evaluation unit ( 6 ) a table (12) is provided, which he reproduces the range of the transmission ( 15 ) depending on the set frequency swing , 12. Apparatus according to claim 11, characterized in that in the event that the evaluation unit ( 6 ) detects a low field strength and at the same time a low error rate, the frequency deviation is optimized to a maximum range using the table (12) ( 13 ) becomes. 13. Device according to one of claims 9 to 12, characterized in that a second table (14) is provided to optimize the transmission behavior in the Auswer teeinheit ( 6 ), which the achievable immunity to interference of the transmission ( 15 ) depending on the set frequency swing reproduces. 14. Apparatus according to claim 13, characterized in that in the event that the evaluation unit ( 6 ) strengthens a high field and at the same time determines a high error rate, the frequency deviation is optimized with the second table (14) for maximum immunity to interference ( 13 ) becomes. 15. Device according to one of claims 9 to 14, characterized, that the optimal frequency swing for a maximum range ge ringer is selected as the frequency swing for a maximum Noise immunity. 16. Device according to one of claims 9 to 15, characterized in that it is laid out for a transmission ( 15 ) according to the DECT standard.