EP1284074A2

EP1284074A2 - Device and method for verifying the reception of a signal with a predetermined frequency

Info

Publication number: EP1284074A2
Application number: EP01947312A
Authority: EP
Inventors: Peter Pessl; Christian Schranz; Alessandro Fulli; Michael Staber
Original assignee: Infineon Technologies AG
Current assignee: Infineon Technologies AG
Priority date: 2000-05-24
Filing date: 2001-05-23
Publication date: 2003-02-19
Also published as: CN1168270C; CN1430843A; US20030179822A1; JP2003534702A; KR20030003756A; DE10025581A1; KR100559934B1; WO2001091309A3; US7224751B2; WO2001091309A2

Abstract

A device and method are disclosed, whereby the normally complicated and difficult frequency determination is achieved by simply arranged and executed measures, namely by means of larger, smaller and/or equal comparisons and a counting of certain events. The invention further relates to arrangements whereby the noise signal level, or the influence thereof on the verification to be carried out is reduced.

Description

description

Device and method for checking whether a signal is received at a predetermined frequency

The present invention relates to a device according to the preamble of claims 1, 5 and 7, and a method according to the preamble of claims 15, 16 and 17, i.e. an apparatus and a method for checking whether a signal is received at a predetermined frequency.

Such a device and such a method are required, for example, in the case of the so-called "splitterless integrated voice and data linecard".

Splitterless integrated voice and data linecards are electrical printed circuit boards which are used in telecommunications switching centers (hereinafter referred to as central offices). It is up to you

receive voice data received from telecommunications subscribers (hereinafter referred to as clients), identify them as voice data, convert them into PCM-coded data, and forward them, and

to receive data coming from an XDSL modem present at the client (hereinafter referred to as client modem) via the same line as the voice data, than to identify data coming from a client modem, in ATM-coded data implement and forward.

Splitterless integrated voice and data line cards can be designed differently. The presently contemplated splitterless integrated voice and data line card is a Li-te version that is standardized in ITU G.lite ^'. ITU G.lite allows parts of the splitterless integrated voice and data linecard to be put into an energy-saving mode in which they require significantly less energy than in normal operation. To wake up the splitterless integrated voice and data linecard (in order to be able to return the splitterless integrated voice and data linecard to normal operating mode if necessary), ITU G.lite defines a so-called wake-up sequence. Accordingly, the splitterless integrated voice and data linecard must be switched from the energy-saving mode to the normal mode if it receives a signal from the client modem with a certain maximum power and one of three defined frequencies.

The fact that parts of the splitterless integrated voice and data linecard can be put into an energy-saving operating mode has proven to be a great advantage, since an exceptional number of splitterless integrated voice and data linecards can be required in central offices, thus making considerable energy savings possible.

The use of the possibility of putting parts of the splitterless integrated voice and data linecard into an energy-saving mode of operation presupposes that the returning to the normal mode of operation functions reliably.

A particular problem here is checking whether a signal is received at one of the frequencies at which the splitterless integrated voice and data linecard has to be reset to the normal operating mode.

This turns out to be difficult

- Because the line between the client modem and the Central Office, over which the wake-up signal is to be transmitted, can be any length of line, and -, consequently one can have very high attenuation (e.g. an approx. 4 km long line can already have approx. -60 dB attenuation),

the transmission of the wake-up signal can be disturbed by noise and by crosstalk,

- Because the wake-up signal may have to pass parts of the splitterless integrated voice and data linecard which are in the energy-saving mode, as a result of which the wake-up signal does not arrive at full power at the device which has to check whether a wake-up signal is received.

There are undoubtedly ways that can be used to reliably detect whether a wake-up signal is being received even under these circumstances. However, no options are known which can be implemented easily, small and inexpensively, and yet function reliably. However, the properties missing from the conventional devices and methods are a very important criterion, in particular because of the very large number in which splitterless integrated voice and data line cards have to be provided.

The present invention is therefore based on the object of finding a device and a method by which it can be reliably checked with little effort whether a signal with a predetermined frequency is received.

This object is achieved according to the invention by the devices according to claims 1, 5 and 7, and by the methods according to claims 15, 16 and 17.

The devices and methods according to the invention are characterized in that - • that the received signal or one on the received

Signal-based signal is compared with one or more threshold values,

• that selected or all changes in the comparison result are counted,

• that the determined number of comparison result changes is compared with one or more predetermined values, and

That the device decides, depending on the result of this comparison, whether or not a signal with the predetermined frequency is received (device according to claim 1), or

That the device repeatedly determines whether a signal with the predetermined frequency is received,

• that a determination result sequence comparison device is provided which compares the sequence of determination results obtained in the repeated determination with one or more predetermined determination result sequences, and

That the device decides, depending on the result of this comparison, whether or not a signal with the predetermined frequency is received

(Device according to claim 5), or

- That a control device is provided which, in the event that a signal is apparently received at a frequency which is substantially higher than the predetermined frequency, changes the device by means of which the noise signal level and / or its influence on the one to be undertaken Check are reduced (device according to claim 7), or

That the received signal or a signal based on the received signal is compared with one or more threshold values, • that selected or all changes in the comparison result are counted,

• that, depending on the result of this comparison, a decision is made as to whether or not a signal with the predetermined frequency is received

(Method according to claim 15), or

- that it is repeatedly determined whether a signal with the predetermined frequency is received,

• that the sequence of determination results obtained in the repeated determination is compared with one or more predetermined determination result sequences, and

(Method according to claim 16), or

- In the event that a signal with a frequency which is substantially higher than the predetermined frequency is apparently received, changes are made to the device carrying out the check, by means of which the noise signal level and / or its influence on the check to be carried out is reduced ( Method according to claim 17).

The claimed devices and the devices required to carry out the claimed methods can largely be implemented in digital technology, as a result of which they can be implemented in a relatively small and simple manner.

In addition, precautions are taken in the claimed devices and methods by means of which the risk of wrong decisions is reduced to a minimum. The claimed devices and methods consequently make it possible, both alone and in combination with one another, to reliably check with little effort whether a signal is received at a predetermined frequency.

Advantageous developments of the invention can be found in the subclaims, the following description and the figures.

The invention is explained in more detail below using exemplary embodiments with reference to the figures. Show it

1 shows a first device for checking whether a signal ^'having a predetermined frequency is received,

Figure 2 shows a second device for checking whether a signal is received at a predetermined frequency, and

FIG. 3 shows a third device for checking whether a signal is received at a predetermined frequency,

The devices described below and the methods described below are optimized for use in the "splitterless integrated voice and data linecard" already mentioned at the beginning; in the example under consideration, the devices are part of a splitterless integrated voice and data linecard. However, there is no restriction to this. The devices and the methods can also be used in any other systems in which it is necessary to recognize the reception of a signal with a predetermined frequency. FIG. 1 shows a first exemplary embodiment of a device which can be used to check whether a signal is currently being received at a predetermined frequency.

The signal with the predetermined frequency is the wake-up signal, which the client modem outputs if necessary, in order to return at least parts of the splitterless integrated voice and data linecard from the energy-saving mode to the normal mode.

The wake-up signal that is to be detected is identified by the reference symbol WUS. In the example under consideration, the wake-up signal can have three different frequencies. The device shown in FIG. 1 first checks whether a wake-up signal having the first wake-up frequency is received, then checks whether a wake-up signal having the second wake-up frequency is received , and finally checks whether a wake-up signal having the third wake-up frequency is received; these reviews are repeated on an ongoing basis.

The wake-up signal WUS first arrives in a bandpass filter BPF. The bandpass filter BPF, more precisely the position of the frequency band that is passed through it, can be set via a control connection fOselect. In the example considered, three different frequency bands can be set. The different frequency bands are selected such that either a wake-up signal having the first wake-up frequency, or a wake-up signal having the second wake-up frequency, or a third wake-up signal Frequency-bearing wake-up signal can be passed.

The output signal of the bandpass filter BPF is fed to an amplifier AMP. This amplifies the signal fed to it. The output signal of the amplifier AMP is fed to a high-pass filter HPF. This is provided in order to filter out the noise generated in the amplifier AMP, in particular the so-called flicker noise component. The said flicker noise component is so strongly attenuated by the high-pass filter HPF that it has no particular influence on the further processing of the signal. In addition, the HPF high-pass filter also eliminates any offset that may be present.

The output signal of the high-pass filter HPF is fed to a comparator COMP. The comparator COMP works with a hysteresis. That .

- The comparator COMP outputs an output signal with a first level when the potential of the signal fed to it exceeds a first (upper) threshold value and maintains this state until the potential of the signal fed to it falls below a second (lower) threshold value , and

- The comparator COMP outputs an output signal with a second level when the potential of the signal fed to it falls below the second - (lower) threshold value, and maintains this state until the potential of the signal fed to it exceeds the first (upper) threshold value.

The threshold values are set in such a way that the noise which is still contained in the signal supplied to the comparator COMP cannot cause a switchover of the output signal of the comparator COMP, that is to say the threshold values are above and below the noise signal level. If the device shown in FIG. 1 is supplied with a signal WUS having one of the wake-up frequencies, and the bandpass filter

BPF allows this signal to pass, there is a wake-up frequency at the output of the comparator COMP. send square wave signal; If the device is supplied with a signal with a frequency that is not passed by the bandpass filter BPF, or if no signal is supplied to the device, the output signal of the comparator COMP remains permanently at level 0 or level 1.

The output signal of the comparator COMP is fed via a switch S to a counter COUNT and triggers it. The counter COUNT thus counts the number of changes in the output signal of the comparator COMP from low to high level (or the number of changes in the output signal of comparator COMP from high to low level). The counting frequency thus corresponds to the frequency of the wake-up signal WUS.

The counter COUNT can "only" count if and as long as the switch S is closed; if the switch S is open, the counter does not receive a trigger signal which causes it to count up. The switch S is normally open and is only closed for a specific time. Before the switch S is closed, the counter is reset by applying a corresponding signal to a reset connection reset thereof. If the switch S is then closed for the predetermined time, the counter counts during this time with a counting frequency corresponding to the frequency of the wake-up signal WUS. Counting ends when switch S is opened.

The count reached after opening the switch S is fed to a comparison device CU which compares it with one or more values which are stored in a look-up table provided in the comparison device or elsewhere.

The values stored in the look-up table are selected so that if the count of the counter COUNT matches one of these values, that a wake-up signal having a wake-up frequency is received.

The fact that the count of the counter COUNT is not only compared with one value, but with several values makes it possible to decide that a signal with one of the wake-up frequencies is also received,

- if the frequency of the received signal does not exactly match one of the wake-up frequencies, and / or

- If disturbances in the transmission or evaluation have resulted in the meter reading of the meter deviating more or less from the meter reading that would have been reached in the undisturbed case.

Alternatively, provision can be made in the look-up table to define one or more value ranges within which the count of the counter COUNT must lie so that it can be assumed that a wake-up frequency having a wake-up frequency Signal is received.

The comparison device CU and / or the look-up table have a control connection, not shown in FIG. 1, via which it is possible to set, with which value or with which values the count of the counter COUNT is to be compared. These values are different for the different wake-up frequencies. Alternatively, it can be provided that the switch S is closed depending on the wake-up frequency for which the received signal is currently being examined, so long that the same count results for all wake-up frequencies.

The comparison device CU outputs a signal representing the result of the comparison. At the same time, this signal signals whether a wake-up signal having one of the wake-up frequencies is being received, and can be considered a OJ OJ t MF ¹ F ¹

<-π o LΠ o U1 σ <-n

The device shown in FIG. 2 is distinguished from the device shown in FIG. 1 in that the decision as to whether or not a signal having one of the wake-up frequencies is received is based on a more or less long sequence of results takes place, which are obtained in a repeated determination as in the device according to FIG. 1 or carried out differently as to whether a signal having one of the wake-up frequencies is received or not.

In the example considered, the device shown in FIG. 2 completely contains the device shown in FIG. 1 and described with reference to it, but additionally has a digital evaluation logic (provided behind the comparison device CU); in the example under consideration, this digital evaluation logic consists of a shift register SR and a second comparison device (a determination result sequence comparison device) CU2.

In contrast to the device according to FIG. 1, the output signal of the comparison device CU is not already used as the output signal of the device. Instead, it is decided (by the shift register SR and the second comparison device CU2) depending on the course of the output signal of the comparison device CU whether a signal having one of the wake-up frequencies is being received.

The output signal of the comparison device CU is fed to the shift register SR, and transferred to it with a clock clock and pushed on. The clock clock preferably has the same frequency as the signal used to control the switch S. As a result, the time course of the output signal of the comparison device CU is recorded in the shift register SR.

The content of the shift register SR is fed to the second comparison device CU2 and in this with one or a plurality of reference bit patterns refpat also supplied to the second comparison device CU2 are compared. The second comparison device CU2 has a control connection via which it is possible to set, with which reference bit pattern or with which reference bit pattern the content of the shift register is to be compared. The signal fOselect controlling the bandpass filter BPF can be applied to this control connection. This is necessary because the data contained in the shift register SR are the result of successive different checks; Depending on the frequency, the reception of which is to be checked by the second comparison device CU2, different reference bit patterns refpat must be used.

The comparison device CU2 outputs a signal representing the result of the comparison. This signal also signals whether a wake-up signal having one of the wake-up frequencies is being received and can therefore be used as the wake-up bit WUB, which sets the energy-saving mode back Parts of the splitterless integrated voice and data linecard are put into normal operating mode.

The reference bit patterns are selected in such a way that it is only decided that a signal having one of the wake-up frequencies is received if this is done by the comparison device CU a predetermined number of times in succession and / or a predetermined number of times within one predetermined period of time was determined.

This can prevent a decision, that a signal with one of the wake is being made, due to a disturbance which happens to have the consequence that the output signal of the comparison device CU incorrectly signals the reception of a signal with one of the wake-up frequencies -Up- frequencies is received. i4

The device shown in FIG. 2 and described with reference to it for checking whether a signal is received at a predetermined frequency thus works even more reliably than the device shown in FIG. 1 and described with reference to it.

An even more reliable check as to whether a signal with a predetermined frequency has been received is possible using the device shown in FIG.

The device shown in FIG. 3 contains the device shown in FIG. 2 and described with reference to FIGS. 1 and 2, but additionally has a digital adaptation logic which adjusts the amplifier AMP taking into account the given conditions so that the checking, whether a wake-up signal is received, can under no circumstances be disturbed by noise or other interference; In the example under consideration, this digital adaptation logic consists of a memory device formed by a flip-flop FF in the present case and a gain setting device AMPCTL.

The flip-flop FF is connected to a terminal OV indicating an overflow of the counter COUNT. It temporarily stores the meter's connection OV

COUNT output signal and passes this to the gain adjuster AMPCTL.

The gain setting device AMPCTL causes one depending on the value of the signal supplied to it by the flip-flop FF

Change in the amplification factor of the amplifier AMP; it reduces the amplification factor if the signal supplied to it by the flip-flop FF indicates an overflow of the counter and / or it increases the amplification factor if the signal supplied to it by the flip-flop FF does not indicate an overflow of the counter. This procedure is based on the knowledge that the counter COUNT can only overflow if the signal output from the amplifier AMP has too much noise, more precisely an excessively high noise signal level. A high noise signal level causes the output signal of the comparator COMP to change much more often than would be the case if a signal having no noise or low noise (a low noise signal level) were supplied to the comparator. If the noise signal level exceeds the threshold values of the comparator, the output signal of the comparator changes so often that the counter COUNT triggered by this signal overflows within the time during which the switch S is closed. The prerequisite for this is, of course, that a counter is used, the maximum count of which is not very much higher than the count which is reached when an undisturbed signal having one of the wake-up frequencies is supplied to the comparator, or that a counter is used which overflows when a signal having a noise signal level exceeding the comparator thresholds is supplied to the comparator; the provision of such a counter has no negative effects on the function and the feasibility of the device and can therefore be carried out without problems. The overflow of the counter COUNT is a clear indication that the signal fed to the comparator COMP has so much noise that it is no longer possible to reliably detect a signal having one of the wake-up frequencies. However, the noise of the signal fed to the comparator COMP can be reduced by reducing the amplification factor of the amplifier AMP. A lower amplification factor means that the noise component contained in the signal supplied to the splitterless integrated voice and data linecard is less amplified, and moreover an amplifier AMP that amplifies with a lower amplification factor itself generates less noise. A setting of the gain factor of the gain dependent on the count of the counter COUNT. kers AMP is therefore a very simple, yet highly effective way of setting the amplifier's amplification factor to the ideal value.

There are various ways of proceeding with the determination and setting of the optimal gain factor.

A first possibility is that the amplification factor of the amplifier AMP is first set to the maximum value. If the noise signal level is too high, the COUNT counter overflows. This causes the gain adjuster AMPCTL to reduce the gain. If the counter then overflows again (with the reduced amplification factor), the amplification setting device AMPCTL reduces the amplification factor again. This process is repeated until an amplification factor setting has been reached at which the counter no longer overflows. This gain setting, or a gain setting reduced by one or more steps for safety's sake, is then the ideal gain setting that is preferably used in checking whether a signal is received at a predetermined frequency and the most reliable results supplies.

Alternatively, it would also be conceivable to first set the amplification factor of the amplifier AMP to the minimum value, then to increase it until the counter overflows, and then to reduce it again by one or more steps.

It would also be conceivable to first set the amplification factor of the amplifier AMP to a value which lies between the minimum and the maximum value, and to gradually reduce the amplification factor based on this (if the Counter indicates an overflow), or incrementally (if the counter shows no overflow).

It should be clear that the determination and setting of the optimal amplification factor can also be carried out any other way than described above. In particular, the size and / or the number of stages in which the amplification factor is changed can, among other things, be determined and / or varied as desired.

It generally proves to be advantageous if the amplifier AMP has a plurality of amplifier stages, the amplification factors of which can be changed in stages of different sizes. In the example under consideration, the amplifier AMP comprises two ner amplifier stages, designated by the reference numerals AMP1 and AMP2 in FIG. 3, the amplification factor of the first amplifier stage AMP1 being changeable in large steps, and the amplification factor of the second amplifier stage AMP2 being changeable in comparatively small steps.

A gain factor setting as described or in a different way enables the splitterless integrated voice and data linecard to be optimally adapted to the particular circumstances, in particular the length of the line between the client modem and the central office (attenuation) and the existing interference adapt.

It should be clear that the overflow of the COUΝT counter does not necessarily have to be used as the triggering event for the measures described. Alternatively, reaching or exceeding a certain other count can be used as the triggering event. Reaching or exceeding the specific count can be detected by monitoring the count output by the counter or selected (preferably the most significant) bits thereof. The same result or a similar result can be achieved if, depending on the count reached in the counter or other parameters providing information about the noise signal level or other disruptive influences, additionally or alternatively on the bandpass filter BPF, the high-pass filter HPF and / or the comparator (for example on the threshold values used by this) is influenced.

The devices and methods described make it possible, regardless of the details of the practical implementation, to check with little effort, but nevertheless extremely reliably, whether a signal with a predetermined frequency is received.

If, as in the example under consideration, it is to be checked whether the received signal has one of several different frequencies, it can prove to be advantageous if the device described also provides information about which of the frequencies to be detected has the received signal. This information can also be obtained from the described

Devices are obtained: the comparison devices CU and CU2 can - if necessary taking into account the current or previous value of the control signal fOselect - recognize from the comparison result (from the knowledge in which of the comparisons to be carried out there was a match) which of the frequencies to be detected the received signal having.

Claims

claims

1. A device for checking whether a signal is received at a predetermined frequency, that is, whether it is being used,

that the received signal or a signal based on the received signal is compared with one or more threshold values,

- that selected or all changes in the comparison result are counted,

- That the determined number of comparison result changes is compared with one or more predetermined values, and

- That the device depending on the result of this comparison decides whether a signal with the predetermined frequency is received or not.

2. Device according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the comparison of the received signal or the signal based on the received signal with one or more threshold values is carried out by a comparator,

which outputs an output signal having a first level when the potential of the signal supplied to it exceeds an upper threshold value,

which outputs the output signal having the first level until the potential of the signal supplied to it falls below a lower threshold value,

- which outputs a second level output signal when the potential of the signal supplied to it falls below the lower threshold, and

- Which outputs the output signal having the second level until the potential of the signal supplied to it exceeds the upper threshold value.

3. Apparatus according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the changes in the comparison result are counted by a counter triggered by the output signal of the comparator.

4. Apparatus according to claim 3, d a d u r c h g e k e n n z e i c h n e t that the output signal of the comparator is only forwarded to the counter for a predetermined time.

5. Device for checking whether a signal with a predetermined frequency is received, that is, that the device repeatedly determines whether a signal with the predetermined frequency is received,

a determination result sequence comparison device is provided which compares the sequence of determination results obtained in the repeated determination with one or more predetermined determination result sequences, and

6. The apparatus of claim 5, wherein the results that the results obtained upon repeatedly determining whether a signal is received at the predetermined frequency are written to a shift register.

7. Device for checking whether a signal is received at a predetermined frequency, characterized in that a control device is provided which, in the event that a signal is apparently received at a frequency which is substantially higher than the predetermined frequency, changes. the device reduces the noise signal level and / or its influence on the check to be carried out.

8. The device according to claim 7, d a d u r c h g e k e n n z e i c h n e t that the change consists in that an amplifier contained in the device is influenced to amplify the signal to be detected.

9. The device according to claim 8, d a d u r c h g e k e n n z e i c h n e t that the amplification factor of the amplifier is reduced.

10. Device according to one of claims 7 to 9, that the change consists in that an influence is exerted on a filter contained in the device for filtering the signal to be detected.

11. Device according to one of claims 7 to 10, that the change consists in that a comparator contained in the device compares the signal to be detected with one or more threshold values

Is influenced.

12. The apparatus of claim 11, d a d u r c h g e k e n e z e i c h n e t that the or the threshold values, with which the signal to be detected is compared, are changed.

13. Device according to one of claims 7 to 12, characterized in that the changes are carried out when a counter provided for determining the frequency of the received signal exceeds a predetermined count.

14. The apparatus of claim 13, d a d u r c h g e k e n n z e i c h n e t that the changes are made when the counter overflows.

15. A method for checking whether a signal is received at a predetermined frequency, that is to say whether it is received,

that selected or all changes in the comparison result are counted,

- That it is decided depending on the result of this comparison whether a signal with the predetermined frequency is received or not.

16. A method for checking whether a signal is received at a predetermined frequency, that is, whether it is being received,

- it is repeatedly determined whether a signal with the predetermined frequency is received,

- that the sequence of determination results obtained in the repeated determination is compared with one or more predetermined determination result sequences, and

17. A method of checking whether a signal is received at a predetermined frequency, since you rch marked that in the event that a signal is apparently received at a frequency which is substantially higher than the predetermined Frequency, changes are made to the device carrying out the check, by means of which the noise signal level and / or its influence on the check to be carried out is reduced.