The invention is based on a method for correcting at least one transmission parameter for data transmission between a sensor unit and a control unit of the generic type of the independent patent claim 1. The subject matter of the present invention is also a device for carrying out such a method.
Peripheral sensor interface 5 (PSI5) is an open standard. On the basis of the previous PASO protocol, the PSI5 standard supports applications in which up to four sensors per bus node can be interrogated in different configurations by a control unit. Bidirectional communication for sensor configuration and diagnosis is also provided.
In airbag systems, for example data from pressure sensors or acceleration sensors is evaluated via current-modulated two-wire buses which communicate with the control unit via a Manchester-encoded protocol. The PSI5 standard also defines possible operating modes. They are firstly differentiated into synchronous and asynchronous operating modes. In the case of the synchronous operating modes, depending on the connection of the sensors to the control unit there are three operating modes: parallel BUS mode in which the sensors are connected in parallel, universal BUS mode in which the sensors are connected in serial fashion and daisy chain BUS mode. Combined with other parameters, such as the total number of time slots, data rate, data word length, parity/CRC monitoring, the PSI5 standard permits different implementation possibilities. The use of a 10 bit data word length is widespread.
Owing to oscillator clock tolerances at the sensor, the number of bits which can be transmitted within a PSI5 communication mode is limited. For example, 10 bit sensor data can be transmitted within a 125 k communication mode in three different communication slots, even if the oscillator clock of the sensor can deviate by ±5% over its service life. However, in known methods it is not possible to communicate with three bus users within four communicate slots in the 16 bit mode at 189 k if there is an oscillator deviation of ±5% since otherwise data collisions can occur on the bus.
The method for correcting at least one transmission parameter for data transmission between a sensor unit and a control unit having the features of independent claim 1 and the device for correcting at least one transmission parameter for data transmission between a sensor unit and a control unit having the features of independent patent claim 6 each have the advantage that by correcting at least one transmission parameter, fault-free transmission with the PSI5 standard can be made possible in any desired communication modes over the service life of the vehicle even if the sensor oscillator clock can deviate over the service life of the vehicle. Therefore, embodiments of the present invention permit satisfactory data transmission by means of the PSI5 standard even when the oscillator clock of the sensor unit is disrupted to a certain extent, and certain, chronologically very tight PSI5 communication modes are to be implemented. This can advantageously improve safety in road traffic, since sensor units with a defect sensor oscillator can nevertheless still transmit data within a specific range. As a result, incorrect failures to trigger can be minimized.
The embodiments of the present invention make available a method for correcting at least one transmission parameter for data transmission between a sensor unit and a control unit. A sensor oscillator generates a sensor clock signal with a predefined period length, wherein the at least one transmission parameter is determined on the basis of the sensor clock signal. In addition, a reference clock signal which is generated by a reference oscillator with a predefined reference period length is received. In this context, the sensor clock signal is compared with the reference clock signal, wherein a deviation of the current period length of the sensor clock signal from a setpoint period length is determined on the basis of the comparison, and wherein the at least one transmission parameter is corrected on the basis of the determined deviation.
In addition, a device for correcting at least one transmission parameter for data transmission between a sensor unit and a control unit is proposed. A sensor oscillator generates and outputs a sensor clock signal with a predefined period length, wherein the at least one transmission parameter is determined on the basis of the sensor clock signal. A reference oscillator generates and outputs a reference clock signal with a predefined reference period length. In this context, the device for correcting at least one transmission parameter comprises an oscillator monitor which receives the sensor clock signal and the reference clock signal and carries out the method for correcting at least one transmission parameter.
The device for correcting at least one transmission parameter for data transmission between a sensor unit and a control unit can be understood here to be an evaluation and control unit which is arranged in the sensor unit and which processes and evaluates acquired sensor signals.
The evaluation and control unit can have at least one interface which can be embodied by means of hardware and/or software. In a hardware embodiment, the interfaces can be, for example, part of what is referred to as a system ASIC which includes a wide variety of functions of the evaluation and control unit, such as for example the function of the oscillator monitor. However, it is also possible for the oscillator monitor and/or the interfaces to be separate, integrated circuits or at least partially composed of discrete components. In the case of a software embodiment, the interfaces can be software modules which are present, for example, on a microcontroller along with other software modules. It is also advantageous to have a computer program product with program code which is stored on a machine-readable carrier such as a semiconductor memory, a hard disk memory or an optical memory and is used to carry out the evaluation when the program is executed by the evaluation and control unit.
A sensor unit is understood here to be a component which comprises at least one sensor element which directly or indirectly senses a physical variable or a change in a physical variable and preferably converts it into an electrical sensor signal. The sensor unit can therefore be embodied, for example, as an acceleration sensor or as a pressure sensor or as a rotational speed sensor with corresponding sensor elements. The sensor unit can be installed, for example, in a vehicle bumper in order to detect collisions with pedestrians. In order to detect side collisions, in one embodiment as an acceleration sensor the sensor unit can be installed on the B, C or D pillar of the vehicle, or in an embodiment as a pressure sensor it can be installed in the vehicle door. In order to detect front collisions, the sensor unit can be installed as an acceleration sensor in a central control unit or along a flexible crossmember of the vehicle. In order to detect rollovers or skidding, the sensor unit can be installed as a rotational speed sensor in the central control unit or in a separate housing on a vehicle center tunnel. The signals which are output by sensor units are further processed by algorithms within the control unit. If such an algorithm detects that a pedestrian impact, a side collision, a front collision or rollover has taken place, a triggering decision for active restraint means (e.g. airbag) is taken in the vehicle as a function of the detected accident scenario and this restraint means is activated in order to protect the pedestrian in the event of a pedestrian impact or the vehicle occupants in the event of a collision situation.
Advantageous improvements of the method specified in independent patent claim 1 for the correction of at least one transmission parameter for data transmission between a sensor unit and a control unit and the device specified in independent patent claim 6 for correcting at least one transmission parameter for data transmission between a sensor unit and a control unit are possible by virtue of the measures and developments disclosed in the dependent claims.
It is particularly advantageous that a correction factor can be calculated as a function of the deviation and can be applied to the at least one transmission parameter.
In one advantageous refinement of the method according to the invention, the at least one transmission parameter can be adapted in adjustable stages to the determined deviation. As a result, the adaptation of the at least one transmission parameter which can represent, for example, a transmission start time and/or a bit width does not take place suddenly but rather using a slow regulator. Such a slow regulator provides the advantage that the adaptation of the transmission parameters takes place slowly and not suddenly. The data transmission therefore becomes more stable. The adaptation of the transmission parameters takes place using the correction factor. The correction factor can be reduced, for example, by a set stage if the deviation is greater than a predefined threshold value. In addition, the correction factor can be increased by the set stage if the deviation is lower than the predefined threshold value.
Furthermore, the correction factor can remain constant if the deviation is equal to the predefined threshold value. For example the value 0 can be predefined as the threshold value.
In one advantageous refinement, the device according to the invention can comprise a counter which counts pulses of the sensor clock signal. In this context, the oscillator monitor can start the counter at a start time at which the oscillator monitor receives a first synchronization pulse of the reference clock signal and stop the counter at a stop time at which the oscillator monitor receives a subsequent second synchronization pulse. The use of the counter permits particularly simple and cost-effective implementation of the device according to the invention for correcting at least one transmission parameter. Therefore, the oscillator monitor can read out a counter reading of the counter and compare it with a setpoint counter reading which is calculated from the ratio of the reference period length to the setpoint period length of the sensor clock signal. The setpoint counter reading can be calculated, for example, by the oscillator monitor or in advance and stored in a non-volatile memory in the sensor unit. On the basis of the comparison, the oscillator monitor can determine a deviation of the current period length of the sensor clock signal from a setpoint period length.
In a further advantageous refinement of the device according to the invention, on the basis of a predefined tolerance range for the deviation, the oscillator monitor can calculate an acceptance window which can be limited downward by a first counter reading and upward by a second counter reading. The typical tolerances of the sensor clock signal are approximately ±3.5% over its service life. An upper limit for oscillator clock deviations in the individual sensor units is currently ±5% according to the PSI5 standard. The tolerance of the reference clock signal is ±1%. The acceptance window can therefore be predefined with an additional safety interval. Therefore, the acceptance window can be predefined, for example, with an outer limit of ±10%. The outer limit of the exemplary acceptance window results from the tolerance of the sensor oscillator of ±5%, the tolerance of the reference clock signal of ±1% and the safety interval which has, for example, a value of ±4%. The safety interval is selected such that the transmission of data into a triggering algorithm of restraint systems does not bring about any appreciable deviation of triggering times.
In a further advantageous refinement of the device according to the invention, the oscillator monitor can adapt the correction factor to the determined deviation and correct the at least one transmission parameter with the adapted correction factor if the current read-out counter reading lies within the acceptance window.
Furthermore, the oscillator monitor can interpret the second synchronization pulse as a new first synchronization pulse and restart the counter if the current read-out counter reading lies within the acceptance window. In addition, the oscillator monitor can interpret the second synchronization pulse as an interference pulse if the corresponding current read-out counter reading is lower than the first counter reading. In this case, the oscillator monitor can ignore the second synchronization pulse which is interpreted as an interference pulse and not carry out any adaptation of the correction factor or correction of the at least one transmission parameter. Furthermore, the oscillator monitor can interpret the second synchronization pulse as a new first synchronization pulse if the corresponding current read-out counter reading is higher than the second counter reading. In this case, the oscillator monitor can restart the counter in reaction to the second synchronization pulse, which is interpreted as a new first synchronization pulse, and can correct the at least one transmission parameter with an already existing correction factor. As a result, in embodiments of the present invention the data transmission advantageously becomes even more robust with respect to EMC interference from the outside, which can give rise to artificial synchronization pulses or a lack of synchronization pulses. In addition, this can advantageously prevent a situation in which EMC interference can bring about a change in the correction factor.
One exemplary embodiment of the invention is illustrated in the drawing and is explained in more detail in the following description. In the drawing, identical reference symbols denote components and/or elements which execute the same or analogous functions.
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In the illustrated exemplary embodiment, the device 20 for correcting at least one transmission parameter is embodied as an application-specific integrated circuit (ASIC) which comprises at least one computer unit or at least one microcontroller and processes and evaluates sensed sensor signals.
As is also apparent from
The method for correcting at least one transmission parameter can be implemented, for example, using software or hardware or in a mixed form from software and hardware in the individual sensor units 10.
In the illustrated exemplary embodiment, the reference clock signal RTS has a frequency of 2 kHz and a reference period length T_ref of 500 μs±1%. In the illustrated exemplary embodiment, the sensor clock signal STS has a frequency of 18 MHz and a setpoint period length T_STS_soll of 0.0555 μs. In order to detect the deviation Delta_t of the sensor clock signal STS of the sensor unit relative to the reference clock signal RTS of the control unit 30, the deviation Delta_t is therefore calculated according to equation (1).
Delta_t=T_ref−N*T_STS where N=T_ref/T_STS_soll (1)
For the values as specified above, a value of 9000 is obtained for the factor N. In a further step, proportional adaptation of the transmission start time t_NS based on the PSI5 standard and of the bit widths t_Bit is carried out as a function of the deviation Delta_t of the sensor clock signal STS and the reference clock signal RTS in the respective sensor unit 10 before data transmission. In this way, a data collision does not occur on the PSI5 transmission bus even if the sensor clock signal STS of the sensor unit 10 can deviate by up to ±10% from the nominal case in the illustrated exemplary embodiment. The typical tolerances of the sensor clock signal STS are ±3.5% over the service life. The permitted upper limit for deviations of the sensor clock signal STS in the respective sensor unit 10 is ±5% according to the PSI5 standard. In the illustrated exemplary embodiment, the range for the correction of the at least one transmission parameter starts at a deviation Delta_t of ±0% and ends at a deviation Delta_t of approximately ±10%. This also corresponds to an acceptance window AF which is illustrated in
The deviation adaptation of the transmission start times t_NS and of the bit widths t_Bit does not take place suddenly within the scope of the invention but rather using a slow regulating function. Such a slow regulating function provides the advantage that the adaptation of the transmission start times t_NS and of the bit widths t_Bit takes place slowly and not suddenly. The data transmission therefore becomes more stable. In order to permit transient recovery of the regulating function within a first initialization phase of the sensor unit 10 and therefore already to ensure fault free data transmission of sensor status data in a second initialization phase, a minimum regulating speed in the first initialization phase is set to at least 60%/s. In this context, the first initialization phase lasts at least 50 ms. The control unit 30 starts the transmission of the reference clock signal RTS approximately 10 ms after the switching on. For the transient recovery of the reference clock signal RTS, a further 5 ms are provided. Therefore, in the first initialization phase 35 ms or 70 synchronization pulses SP1, SP2 are still available for the transient recovery of the regulating function. With the lowest regulating rate of 2%/0.035 s, a regulating rate of 57.1%/s is obtained.
With a maximum permitted deviation Delta_t of the sensor clock signal STS of 5%, a regulating rate of 57.1%/s*1.05%=60.0%/s is obtained. After the first initialization phase, the regulating function for the transmission start times t_NS and bit widths t_Bit is operated more slowly. For this purpose, various regulating rates RR can be stored in a memory (not illustrated in more detail). For example the following values for the regulating rate RR: ±0.0625%/s, ±0.03215%/s, ±0.125%/s, ±0.25%/s, ±0.5%/s, ±1%/s, ±2%/s, ±4%/s are stored for the illustrated exemplary embodiment.
The adaptation of the at least one transmission parameter or of the transmission start times t_NS and of the bit widths t_Bit to the determined deviation Delta_t takes place using a correction factor KF in adjustable stages.
This means that the correction factor KF is obtained over time as a stage (KF=ΣRR) as a function of the set regulating rate RR. In this context, the correction factor KF is reduced by the set regulating rate RR if the determined deviation Delta_t is greater than a predefined setpoint value of, for example 0. If the determined deviation Delta_t is lower than the predefined setpoint value, the correction factor KF is increased by the regulating rate RR. If the determined deviation Delta_t is equal to the predetermined setpoint value, the correction factor KF is not changed and remains constant.
The correction factor KF is applied according to equation (2) to the transmission start time t_NS, and according to equation (3) to the bit width t_Bit.
t_NS,KF=(KF*t_NS)+t_NS (2)
t_Bit,KF=(KF*t_Bit)+t_Bit (3)
In the illustrated exemplary embodiment, the device 20 for correcting at least one transmission parameter comprises a counter 24 which counts pulses of the sensor clock signal STS. The method of functioning of the device 20 for correcting at least one transmission parameter from
Delta_t=(ZS_soll−ZS)*T_STS_soll (4)
On the basis of the predefined tolerance range of ±10% for the deviation Delta_t, the oscillator monitor 22 calculates the acceptance window AF which is limited downward by a first counter reading ZS_min of 8100 here, and upward by a second counter reading ZS_max of 9900 here. The oscillator monitor 22 corrects the at least one transmission parameter on the basis of the determined deviation Delta_t if the current read-out counter reading ZS lies within the acceptance window AF.
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Embodiments of the present invention provide the further advantage that the data transmission becomes even more robust with respect to EMC interference from the outside. Finally, no adaptation of the correction factor is to be carried out in the case of EMC interference.
Number | Date | Country | Kind |
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10 2017 217 723.3 | Oct 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/075275 | 9/19/2018 | WO | 00 |