EP2338066A1

EP2338066A1 - Device and method for inspecting a frequency-modulated pulse generator

Info

Publication number: EP2338066A1
Application number: EP09782155A
Authority: EP
Inventors: Hans-Georg Drotleff
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2008-10-15
Filing date: 2009-08-25
Publication date: 2011-06-29
Also published as: DE102008042847A1; WO2010043439A1; US20110140740A1; US8564379B2; JP2012506033A; JP5579186B2

Abstract

The invention relates to a method and to a device for inspecting a frequency-modulated pulse generator (1), the device comprising: a cycle counting unit (5, 24) for counting pulse cycles (f_SSO) of the pulse generator (1, 17, 34) in multiple successive measurement time frames (T_m) particularly defined by a measurement signal (m) having a measurement frequency (f_m), and for outputting cycle counts (z), and a comparison unit (6, 7, 8) for receiving and comparing the cycle counts (z) to each other and for outputting at least one output signal (S2, S6) as a function of the comparison. For this purpose detected maximum and minimum values may be compared to each other.

Description

description

title

Apparatus and method for checking a frequency modulated clock

State of the art

Electromagnetic interference or interference (EMC) is subject to strict regulations. Here, EMC limit values are set in order to limit the load to a minimum and thereby avoid damage to humans and other systems. The limits may relate in particular to which intensities per frequency range may be emitted by electronic devices or systems.

Clocks are generally formed as integrated circuits (ICs) and are used in electronic systems for outputting a clock signal. They are designed in particular as oscillators or frequency synthesizers and output a clock signal having a nominal frequency or center frequency. Although clocks contribute significantly to the proper functioning of mostly digital systems, they are at the same time the EMC main generator sources in electronic circuits.

Reducing or limiting EMC emissions is therefore an important goal in the development of digital systems that use clocking or frequency generating components in their systems.

Shielding, coatings, or special filter components are known to reduce EMC emissions. Due to the ever higher power densities, in particular the higher clock speeds and the ever stricter E MV regulations, however, such measures fall on their efficiency and cost limits.

Therefore, spread spectrum oscillators (SSO) are increasingly being used to limit peak emissions. These scatter their clock signal over a wide teres frequency spectrum and thus limit the peak emissions related to the individual frequency ranges. This dispersion is generally achieved by a frequency modulation with a modulation frequency well below the clock frequency. The modulation signal can z. B. have a triangular shape or any other convenient form. By such SSO can be z. B. achieve a peak emission reduction of up to 20 dB. A spread spectrum oscillator is known for example from German patent application DE 10 2005 013 593 A1.

Superimposed on the frequency modulation is the oscillator-typical cycle-to-cycle jitter, which generally causes much greater fluctuations than the frequency modulation, but is already released over a few clock cycles.

The frequency modulation is generally achieved by an additional circuit; In this case, however, can not be directly recognized during operation, whether this frequency modulation is correct. Furthermore, it can not be easily recognized in an electronic system whether an SSO has actually been installed or z. B. erroneously an oscillator with a fixed frequency. In this case, therefore, a significant EMC pollution of the environment may occur without this being directly detectable in the device or electronic device.

Although in principle methods and systems are known to check a proper frequency modulation of a SSO, z. B. by FM demodulation and subsequent evaluation of the modulation signal or by a frequency spectrum analyzer. However, such measures are complicated and require extensive measurement technology. Nor can they be readily adapted to an existing production testing technique.

Disclosure of the invention

According to the inventive method and the device according to the invention, the clock cycles of the clock, in particular an SSO, counted in a measuring period. In particular, the measurement periods may be fixed in order to achieve directly comparable values; in principle, however, they can also be adjusted during the measurement; so z. B. the measurement period in Depending on the determined modulation frequency can be adjusted below. The count values or cycle counts determined in several measurement periods are subsequently compared; In particular, they can be compared with each other. The frequency modulation to be checked should thus lead to a change in the cycle counts in successive measurement periods.

The invention is based on the idea that the modulation frequency of a frequency-modulated clock, in particular an SSO, is substantially smaller than the center frequency of the clock. Thus, according to the invention, individual clock cycles or clock oscillations within a measuring period are counted by a counter, namely the cycle counter, which in particular is digital and determines cycle counts. Due to the frequency modulation, the number of clock cycles occurring in fixed measurement periods should vary; in the absence of frequency modulation, fixed or slightly fluctuating values should result.

The measurement periods are advantageously determined by a measurement signal with corresponding measurement frequency. The measuring frequency should preferably be at least twice as high as the modulation frequency in order to satisfy the sampling theorem. It may advantageously be two to seven times the modulation frequency. If the measuring frequency is chosen too large, the quantitative determination of the modulation frequency and thus of the spread or the scattering is again made more difficult.

The cycle counter can in particular be reset directly by the measuring signal. Thus, a simple metrological structure with a direct determination of the different cycle counts or cycle counter readings is possible, which are subsequently read out over several measurement cycles or measurement periods, in order to achieve the minimum and maximum cycle count possible. For this purpose, intermediate buffers or intermediate buffers can be used, which are each overwritten with the highest or lowest cycle count determined. Thus, the determined minimum and maximum values, z. B. also by doubble buffering by means of additional result buffer, are evaluated below. The determination or evaluation can then take place after an evaluation period, the more, z. B. 240 or 256 measuring periods, so that should have been made by the sufficient number of minimum and maximum values.

From this, the spread or spread can be determined quantitatively. Furthermore, the nominal frequency, i. in general, the center frequency can be determined.

Further advantageous embodiments arise z. B. by using a measuring number counter to count the number of measurement periods or meter periods and possibly a monitoring counter or watchdog counter. The result can be z. B. binary or output as a PWM signal and used directly in a system.

The method according to the invention and the device according to the invention can be implemented in different ways. In particular, an implementation in a programmable logic device, for. As an FPGA or ASIC done. In such an implementation in an IC, a relatively small amount of hardware or a small chip area is required, the z. B. essentially by the cycle counter, the buffer, possibly input and output flip-flops, a logic circuit and possibly a clock processing for the male, to be examined clock signal can be formed. Optionally, an internal oscillator or clock generator for generating the measuring frequency may also be provided, for. B. also an existing internal clock signal, in which case by z. B. an internal switching device switching between this internal clock and an external measurement signal can be made possible. Furthermore, the device according to the invention can also be integrated together with the clock or SSO.

Further embodiments are as independent testing means, in which the inventive device and optionally further components are mounted on a circuit board, and z. B. as a peripheral module in a microcontroller. The output of the measurement result depends on the implementation form or the product characteristics.

Brief description of the drawings Fig. 1 shows a modulation profile of a spread spectrum oscillator as a frequency versus time;

Fig. 2 shows EMC frequency spectra of an oscillator with and without frequency modulation;

Fig. 3 shows a block diagram of an FPGA implementation of the device according to the invention;

3a shows a block diagram of another FPGA implementation of the device according to the invention; FIG. 44 shows a block diagram of a test arrangement in which the device according to the invention is used as an independent testing device;

Fig. 5 shows an integration of the method in an electronic system for activation / evaluation only in the production;

FIG. 6 shows an integration of the method according to the invention in a device on a circuit carrier during activation / evaluation of the device

Measurement online in operation;

Fig. 7 shows the device as an independent component;

Fig. 8 shows the device according to the invention when integrated with an SSO;

Fig. 9 shows the integration with a microcontroller; Fig. 1100 shows for an implementation example the frequency modulation and details of the measurement signal;

Fig. 1 1 of the calculated counter differences as a function of the measurement modulation frequency ratio in oscillators with different spread.

Embodiments of the invention

An inventive frequency-modulated clock generator is preferably realized in the embodiments shown as SSO, spread spectrum oscillator. FIG. 1 shows the modulation profile of a SSO as a function of the frequency f as a function of the time t. The center frequency fjnid is fixed here; In order to distribute the electromagnetic radiation over a larger frequency range, according to Figure 1, a modulation profile is launched, after which f is periodically modulated between a lower value f_min and an upper value f_max, z. For example, according to the shown triangular line, ie with a linear decrease and increase in the frequency f between f_min and f_max. Basically, other modulations are possible.

Figure 2 shows an EMC frequency spectrum, d. H. the electromagnetic radiation intensity I as a function of the frequency f, in the ninth harmonic of clock oscillators, the curve k1 shows an oscillator with unmodulated frequency f and the curve k2 a spread spectrum oscillator 1. This results in a reduction of the peak emission of the spread spectrum oscillator 1 with respect to the non-modulated oscillator. Outside of the spread, the intensity I given in decibels (dB) drops slowly.

FIG. 3 shows the implementation of the method according to the invention and of the device according to the invention in an FPGA (Field Programmable Gate Array) 2, in a correspondingly highly simplified representation. From an external SSO 1 is a clock signal to be examined with a signal frequency f_sso - in the following, the clock signal is also referred to directly as f_sso - recorded; the signal frequency f_sso is z. B. by superimposing a center frequency fjnid = 33.33 MHz and a modulation frequency f_mod = 10 kHz formed and has z. B. a spread of +/- 2%. The overall arrangement 10 from FIG. 3 is thus formed by the FPGA 2 and the SSO 1. The clock signal to be examined is sent to a clock processing device 3 in the FPGA 2, which outputs a correspondingly processed clock signal having the same frequency f_sso, firstly in the clock input 4a of a flip-flop 4 and secondly in the clock input 5a a (digital) cycle counter 5 is input.

A measurement signal m with the measurement frequency f_m is input to the input 4b of the flip-flop 4 and output from the flip-flop 4 again as a second measurement signal with the same measurement frequency f_m; the flip-flop 4 thus serves only for stabilization and is functionally no longer relevant. The measuring signal m is input to the reset input (reset input) 5b of the cycle counter 5 and thus resets it in each case.

Thus, the SSO frequency to be examined f_sso - in this embodiment, after appropriate preparation in the clock conditioning device 3 - enumerated in the cycle counter 5 over a fixed measurement period T_m, which determines by the externally input measurement signal m with the measurement frequency f_m which resets the cycle counter 5 respectively. The measurement frequency f_m of z. B. 50 kHz is higher than the modulation frequency f_mod of 10 kHz, so that several measurement cycles or cycle counts of the cycle counter 5 are read out during a modulation. The cycle counts are the final counts before cycle counter 5 is reset. If there is actually a modulation, ie fjmod ≠ 0, the cycle counter 5 outputs different cycle counts as signal z, depending on where in the time domain the oscillator modulation curve is in the counting period. If there is no modulation, these values should be the same in the different readout cycles or reset cycles.

The cycle counter 5 outputs its counter readings of each measuring period T_m as signal z (cycle count z) to an upper buffer 6 and a lower buffer 7. The upper buffer 6 contains a maximum intermediate buffer 6a for storing a maximum value and a downstream result. Buffer 6b; Accordingly, the lower buffer 7 contains a minimum intermediate buffer 7a for storing a minimum value and a result buffer 7b. The maximum intermediate buffer 6a is preinitialized with the value 0x0000, the minimum intermediate buffer 7a with the value 0xFFFF. In each measurement period T_m these intermediate buffers 6a, 7a are overwritten with the new cycle count z, if this is smaller than the current value in the minimum intermediate buffer 7a or greater than the current value in the maximum intermediate buffer 6a , The intermediate buffers 6a, 7a are also clocked by the clock frequency f_sso.

After expiry of a convenient number, z. 256, of count periods, the values of the intermediate buffers 6a, 7a are respectively saved in the subsequent result buffer 6b, 7b, which as such is known as doubble buffering. This ensures that the intermediate buffers 6a, 7a can change from counting period to counting period, but the result buffers 6b, 7b are only updated after the intermediate buffers 6a, 7a stabilize or settle, respectively their minimum or have reached maximum meter readings. When outputting the result, only the result buffers 6b, 7b are taken into account, resulting in a stable display. Thus, an evaluation period is formed from a sufficient number of measurement periods. An evaluation device 8 is designed as a logic unit; it accesses the result buffers 6b, 7b and returns a result to an output memory, e.g. B. an output flip-flop 9, which subsequently outputs the output signal S2 as a status output signal. The output flip-flop 9 and the evaluation device 8 are clocked by the clock frequency f_sso.

Furthermore, according to FIG. 3 a, a measurement number counter 13 may be provided which determines the number of measurement periods T_m, i. meter periods), and thus serves to determine the evaluation period. After a suitable number of measurement periods T_m, e.g. 256, the intermediate buffers 6, 7 have stabilized and correlate with the minimum and maximum frequency of the SSO 1, so that the difference of the buffered min and max values Zmin and Zmax of the cycle counter 5 with the spread of the Correlate SSO 1.

Furthermore, in a SSO 1 with central modulation, i. Center Spread Modulation, the mean value [(Zmin + Zmax) / 2] with the center frequency fjnin, thus representing the nominal frequency. In the case of a downspread modulation, Zmin corresponds to the nominal frequency; in the case of an upspread modulation, the maximum value Zmax corresponds to the nominal frequency. The measurement number counter 13 is used to display the first e.g. 16 ignore cycle counts to avoid transients of the measurement signal m. Furthermore, the measuring-number counter 13 is used to determine the time / measurement samples within which the intermediate buffers 6a, 7a stabilize at their max / min values Zmin, Zmax.

Furthermore, a watchdog counter (monitoring counter) 1 1 is advantageously provided, which also counts the number of SSO clock cycles and is reset again with the signal edge of the measurement signal m. The watchdog counter 1 1 counts, in the case of a missing measurement signal m, in contrast to the cycle counter 5 only up to its maximum value and then remains at its max. Counter value stand. This makes it easy to determine whether an expected measurement signal is available. Likewise, the value of this watchdog counter 1 1 can be checked with respect to a valid value range. In this case, a suitable hysteresis is preferably used which takes into account a tolerance of the measurement signal m. Alternatively to the above numerical values can z. B. also has a center frequency f_mid = 55 MHz with + 1-2% spread, a measurement frequency of fm = 100 kHz and a modulation frequency f_mod of z. B. 20 kHz may be provided, whereby meter readings of about 500 can be achieved.

FIG. 4 shows a test arrangement 12, in which an independent testing device 14 is formed, with which an electronic device 16, which has an SSO 17 indicated here, can be examined externally. The electronic device 16 may, for. B. as a circuit with a circuit carrier 20, z. B. a PCB or printed circuit board, the SSO 17 and corresponding other components may be formed. There are - in a conventional manner - via contacting 18, 19, z. B. needle adapter 18, 19, contacts formed for tapping the signals from the device 16 and the signals thus read from the test means 14. The independent test means 17 has z. B. a power terminal 14a, an input 14b for an external measurement signal m2, a ground terminal 14c and a data output 14d for subsequent evaluation via a standard Prüftechnik 22, z. B. another arithmetic unit 22, on. The test means 14 in this case has an FPGA 24 or other programmable switching device, for. B. an ASIC 24, and further an internal clock 25, in particular oscillator 25, for outputting an internal measurement signal m1, wherein the FPGA 24 optionally via an external switching signal (control signal) S4, which switches a switching device 54, between this internal Measuring signal m1 and the external measuring signal m2 can be switched. As an internal clock 25 z. B. an already existing in the system second clock source with a fixed frequency, z. B. from a second oscillator, optionally with frequency division with a PLL z. B. in the FPGA 24 already exists.

Thus, with the independent test means 14, the z. B. may be formed as a test device with housing, the electronic device 16 z. B. in the final inspection or acceptance in the production to be examined. As an output signal S2 can from the output 14d z. B. an oscillator status output signal or a PWM-coded spread signal are output.

Switching between the external measuring signal m2 and the internal measuring signal m1 can be done here by additionally checking the internal measuring signal m1 serve, or also the optional use, if no external measuring signal m2 is available.

FIG. 5 shows the integration of the method according to the invention in an electronic device 26, which has a circuit carrier 27, e.g. B. a PCB or a printed circuit board and mounted on the circuit substrate 27 has a microcontroller 28, an oscillator 30 with a fixed clock for outputting an internal measurement signal m1, an FPGA 32 or other corresponding device and the SSO 34, wherein the components 28, 30, 32, 34 are formed accordingly as integrated circuits. The FPGA 32 may in this case be constructed in accordance with the FPGA 10 of FIG. On the circuit substrate 27 are further contact surfaces 36, 37, 38 provided for tapping by an external test device 40, to which an evaluation device 42 is connected for a standard Prüftechnik. The contact surface 37 serves to supply the measurement signal m from the test device 40 and the contact surface 38 for inputting an initialization signal from the test device 40 for initializing the measurement. At the contact surface 36 z. B. the output of the FPGA 32 as a status output, z. B. as a binary signal or PWM signal output.

FIG. 6 shows an electronic device 44 which differs from the device 26 from FIG. 5 with otherwise identical or corresponding functionality in that the test device or the test device 40 and the evaluation device 42 from FIG. 5 are already integrated in the FPGA 132, so that the activation and evaluation of the measurement can be carried out directly online at the user, ie later in the field for a current functional check. In this case, in Figure 6, an output signal S6 are output from the microcontroller 28 to the outside, for. B. via a data bus 29; when used in a vehicle z. B. the in-vehicle CAN bus 29. The FPGA 132 thus outputs the output signal S2, z. B. as an oscillator status signal to the microcontroller 28, which outputs the corresponding output signal S6 to the outside. Furthermore, the FPGA 132 may have a binary status output 31 to directly trigger an externally connected display device, in particular a signal lamp 46, for direct display of a function check, for. B. with lamp control in proper condition. Thus, by the signal lamp 46, a direct display of the func tioning ability and / or by the output signal S6 also an error message about an already existing user interface.

In FIGS. 5 and 6, the measuring signal m can be used not only as a reset signal for the FPGA 32 or 132, but as shown also as a clock signal for the microcontroller 28 and optionally further components.

Figure 7 shows an implementation in a test and evaluation circuit 52 according to the invention, which is integrated on a semiconductor device. Furthermore, an internal oscillator 53 may be integrated, wherein a switching device 54 switches between an internal measuring signal m1 output by the oscillator 53 and an external measuring signal m2 to be applied if necessary. The SSO signal with the frequency f_sso to be tested is input to an input 50a, the external measurement signal to an input 50b; Furthermore, the switching signal S4 for switching between the internal measuring signal m1 and the external measuring signal m2 can be input via an input 50c; furthermore, an input 5Od for the

Power supply, a ground terminal 5Oe and an output terminal 5Of provided for outputting an oscillator status output signal S2. The functionality of the integrated circuit 50 thus essentially corresponds to that of the independent test means 14 from FIG. 4.

FIG. 8 shows the test and evaluation circuit 52 according to the invention together with the SSO 1 integrated in a semiconductor component 60, ie. H. as a common integrated circuit 60. Thus, in comparison with FIG. 7, the SSO 1 is additionally provided in the integrated circuit. This z. B. only the generated by the oscillator 53 internal measurement signal m1 can be used. The integrated circuit 60 thus has an input terminal 6Od for power supply, an enable input 60a, a clock output 60b, a ground terminal 60c, and an oscillator status output 6Oe for outputting the status output signal S2. Thus, the invention is embodied here as an add-on module in an oscillator IC 60.

FIG. 9 shows a further embodiment in which the device according to the invention is integrated as a peripheral module in a microcontroller 90. In this case, a few conventional devices are initially connected to the internal data bus 91 of the controller 90, in particular an EEPROM 92, a timer / counter or counter 93, an arithmetic logic unit (ALU) 94, an SRAM 95, a program counter 96, a flash program memory 97, an instruction register 98, an instruction decoder 99 for outputting control signals S10, an input output device (IO) 100 , an interrupt unit 101, an analog comparator 102, a control register 103, a status register 104 and a universal serial interface 105, a general purpose register 11 1 and possibly other common facilities of a microcontroller. According to the invention, an SSO verification module 110 is additionally provided, which functionally corresponds essentially to the IC 50 from FIG. 7; Optionally, the internal oscillator 53 can be provided here or else another clock signal present in the microcontroller can be recorded. The SSO clock signal to be examined can be input via an internal SSO of the microcontroller 90 or from an external SSO via a clock input connection 120.

FIG. 10 shows an implementation for monitoring the measurement signal m with a "watchdog" -like counter which counts the number of SSO cycles cyclically from A or C and stops at its maximum counter value if it does not return immediately at A or C. is reset. The period from A to C thus forms the measurement period T_m.

For example, the counter width in [bit] can be construed as log {[spread ^* (f_m-f_mod) + 2 ^* f_mid ^* f_R] / [2 ^* (f_m) ² ]} / log (2)

At time A or C, the watchdog counter is reset cyclically. If measurement signal m is missing, the watchdog counter runs over. This is recognized and further processed as an error and taken into account in the result or the result output. At time A or C, the watchdog counter reading is checked with respect to a validity range including hysteresis.

FIG. 11 shows in a diagram the counter difference Diff as a function of the frequency ratio R, which results as the ratio of the measuring frequency f_m to the modulation frequency f_mod, for three oscillators with different spreads, namely according to curve d1 with 2% spread, d2 with 1 % Spread and d3 = 0.5% spread. The curves thus flatten for larger values of R, so a small value of R, preferably between 2 and 7, should be chosen. Preferably, the measurement frequency f_m is a non-integer multiple of f-mod in order to achieve this. chen that the measuring periods T_m respectively detect different areas of the modulation periods, ie the beginning and end times of the measurement periods T_m are not always in the same phase values of the modulation periods.

Claims

claims

1. A device for checking a frequency-modulated clock (1), the device comprising: a cycle counter (5, 24) for counting clock cycles of a clock signal (f_SSO) of the clock (1, 17, 34) in a plurality of successive measurement periods ( T_m) and for outputting cycle counts (z), and a comparison device (6, 7, 8) for receiving and comparing the cycle counts (z) and outputting at least one output signal (S2, S6) as a function of the comparison.

2. Apparatus according to claim 1, characterized in that the comparison device compares the determined cycle counts (z) with each other and the

Output signal (S2, S6) for evaluating the frequency modulation depending on the relative comparison.

3. Apparatus according to claim 1 or 2, characterized in that the at least one output signal (S2, S6) information about a modulation frequency (fjnod), a nominal frequency (f_mid) and / or a relative dispersion (S) of the clock signal (f_SSO ) contains.

4. Device according to one of the preceding claims, characterized in that the comparison device comprises: a memory device (6, 7) for storing at least minimum and maximum cycle counts and an evaluation device (8) for forming a difference between the minimum cycle counts and the maximum cycle counts and output of the output signal (S2, S6) as a function of the determined difference.

5. Device according to claim 4, characterized in that the storage device (6, 7) has an upper buffer (6) for storing maximum cycle counts and a lower buffer (7) for storing minimum cycle counts, wherein the upper buffer (6) has a maximum intermediate buffer (6a) and the lower buffer (7) has a minimum intermediate buffer (7a), the maximum intermediate buffer (6a) and the minimum intermediate buffer (6a) Buffers (7a) are updated after each measurement period (T_m), the minimum intermediate buffer (7a) being overwritten if the current one

Cycle count (z) is less than the stored minimum cycle count and the maximum intermediate buffer (6a) is overwritten if the current cycle count (z) is greater than the maximum cycle count stored therein.

6. Apparatus according to claim 5, characterized in that the lower buffer (7) and the upper buffer (6) each have a result buffer (6b, 7b) for receiving the value stored in its intermediate buffer (6a, 7a) after a predetermined value Number of counting periods.

7. Device according to one of the preceding claims, characterized in that it comprises a measuring-number counter (13) for counting the number of measuring periods (T_m), wherein the comparing means (6, 7, 8) an evaluation period of several , z. B. two hundred and forty, by the measuring-number counter (13) counted measuring periods (T_m) sets and uses the determined within the evaluation period maximum cycle counts and minimum cycle counts I values to determine the output signal (S2, S6).

8. The device according to claim 7, characterized in that the evaluation period begins at the beginning of a measurement after a predetermined number of counted by the measuring-number counter (13) measuring periods (T_m) and the comparison means (6,7 , 8) ignores the cycle counts for the determination of the output signal (S2, S6) determined in the previous measurement periods (T_m).

9. Device according to one of the preceding claims, characterized in that the measuring period (T_m) by a measuring signal (m) is defined, which is connected to a reset input (5b) of the cycle counter (5) and the cycle counter (5 ) is reset again after a measurement period (T_m), wherein a measurement frequency (f_m) of the measurement signal (m) is greater than the modulation freq. frequency (f_mod) of the modulated clock signal (f_sso).

10. The device according to claim 9, characterized in that the measuring frequency (f_m) is at least twice as large as the modulation frequency (f_mod), which is smaller than a nominal frequency (f_mid) of the clock (1).

1 1. Apparatus according to claim 9 or 10, characterized in that the measuring frequency (f_m) of the measuring signal (m) is a non-integer multiple of the modulation frequency (f_mod), z. B. between two and seven times the modulation frequency (fjnod).

12. The device according to claim 11, characterized in that a monitoring counter (1 1) is provided, which counts the number of clock cycles, by the measuring signal (m), z. B. an edge of the measuring signal (m), is reset and in the absence of a measuring signal (m) counts only up to its predetermined maximum counter value, wherein the comparison means (6, 7, 8), the output signal of the monitoring counter (11) for checking the measuring signal (m) absorbs.

13. Device according to one of the preceding claims, characterized in that it is used as an integrated circuit, preferably programmable integrated circuit, for. As FPGA or ASIC is formed.

14. The device according to claim 13, characterized in that the integrated circuit has an input for the frequency-modulated clock signal to be checked (f_sso), an input (50b) for an external measurement signal (m2) for determining the measurement periods (T_m) and an output for outputting the output signal (S2).

15. The device according to claim 14, characterized in that the integrated circuit further comprises an internal clock generator (53) for outputting an internal measurement signal (m1) and a switching device (54) connected between the input for the external measurement signal (m2) and the internal clock (53) switches.

16. Device according to one of claims 13 to 15, characterized in that it is formed together with the frequency-modulated clock generator (1) as an integrated circuit

17. Device according to one of claims 1 to 12, characterized in that it is designed as a peripheral module (1 10) in a microcontroller (90).

18. Device according to one of the preceding claims, characterized in that the check of the frequency-modulated clock generator (1) by a recorded, external initialization signal (in) is started.

19. Device according to one of the preceding claims, characterized in that as the at least one output signal (S2, S6), a binary signal for status display and / or a data signal (S2, S6), z. B. PWM or digital

Signal is output.

20. Testing device (26, 44) for checking a frequency-modulated clock, comprising at least: a circuit carrier (27), the integrated circuit device (2, 32, 132) according to one of claims 13 to 16, and an internal clock ( 25), wherein the device (2) and the internal clock generator (25) are mounted on the circuit carrier (27).

21. Test device according to claim 20, characterized in that on the circuit carrier (27) further comprises a microcontroller (28) is provided, wherein the output signal (S6) of the device (2) via a data line (29), z. B. bus data line, the microcontroller and / or a binary status output (31) of the device (132) can be output.

22. Method for checking a frequency-modulated clock signal (f_sso), preferably an SSO signal, in which

Clock cycles of the frequency-modulated clock signal (f_sso) are counted in successive measurement periods (T_m), and the cycle counts (z) determined in the measurement periods (T_m) are compared.

23. The method according to claim 22, characterized in that the determined cycle counts (z) are compared with each other and the clock signal (f_sso) in

Depending on the relative comparison.

24. The method according to claim 23, characterized in that a modulation frequency (fjnod) and / or a nominal frequency (f_mid) and / or a relative scattering (S) of the clock signal (f_SSO) is determined and / or evaluated.

25. The method according to any one of claims 22 to 24, characterized in that the measuring periods (T_m) by the measuring frequency (f_m) of a measuring signal (m) are set, wherein the measuring signal (m) to a cycle counter (5) - resets that counts the clock cycles of the clock signal (f_sso).

26. The method according to claim 25, characterized in that over a predetermined number of measurement periods (T_m) a minimum cycle count and a maximum cycle count are determined and from the minimum and maximum cycle count the modulation frequency (fjnod) and / or the nominal frequency (fjnid ) and / or the relative dispersion (S) of the clock signal (f_SSO) is determined and / or evaluated.

27. The method according to any one of claims 22 to 26, characterized in that further a monitoring count is performed, in which the clock cycles are counted such that is counted in the absence of the measurement signal (z) up to a maximum value, and from the counts of the monitoring count on the proper presence of the measuring signal (m) is closed.

28. The method according to any one of claims 22 to 27, characterized in that an evaluation on the basis of a relative dispersion (S) of the determined maximum counts and minimum counts against a nominal frequency, in particular averaged by averaging center frequency (f_mid) is related, wherein a determined relative dispersion with a desired value and, depending on the comparison, the output signal (S2, S6) is output to indicate the state.