EP0933525A1 - Cylinder recognition apparatus and method for a combustion engine - Google Patents

Abstract

The arrangement has a crankshaft sensor (25) detecting a crankshaft angle and a predefined crankshaft position, an ignition device for igniting a cylinder (1-4) with a high voltage pulse in response to suitable control signals, and a controller (100) which outputs control signals to the ignition device depending on the crankshaft signal. The controller outputs a pulse with a predefined attainable amplitude in a defined cylinder on receiving a crankshaft signal during a cylinder detection phase. An ignition detector outputs a signal corresponding to whether and/or with what ignition voltage the defined cylinder is ignited. A cylinder detector determines whether the defined cylinder is in its working cycle at the defined crankshaft position based on the ignition detection signal. AN Independent claim is also included for a method of identifying cylinders in internal combustion engines.

Description

The present invention relates to a device and a Method for cylinder detection in an internal combustion engine (in others also referred to briefly as motor).

In modern motor vehicles, engine management takes place, i.e. the control, regulation and monitoring of the essentials Functions of the engine, usually using a Control unit with a computing device.

In particular, the ignition and fuel injection can be controlled jointly and coordinated with each other respective operating state of the engine can be precisely recorded and at the ignition timing calculation and the fuel rating must become.

One from the computer device for controlling the ignition and fuel injection related important information the position of the crankshaft. Usually a crankshaft sensor provided for detecting the crankshaft position. This crankshaft sensor is, for example, an inductive one Encoder that has a signal for the speed as well as a signal for at least one selected crankshaft position. In the selected crankshaft position is usually the upper one Dead center (TDC) of one or more specific cylinders.

With ignition systems with static ignition high voltage distribution with Individual coils, the computer device needs an additional one Information about the position of the camshaft so that the Ignition coil of the cylinder that is currently in or near the OT of the work cycle is located, can be controlled. Otherwise it could be that the ignition coil of the Cylinder that is currently in or near the TDC of the exhaust stroke is controlled.

The position of the camshaft is usually determined by means of a camshaft sensor, which for example then emits a signal when the camshaft is in one position in which a certain cylinder is at the TDC of its work cycle is. This known method is also called cylinder one detection designated.

From the combination of the signals from the crankshaft sensor and the Camshaft sensor can change the ignition timing and injection timing all cylinders in a clear manner by the computer device be calculated.

The specified method according to the prior art has the Disadvantage that two expensive sensors and one accordingly complex wiring is required.

The object of the present invention is a device and a method for cylinder detection in an internal combustion engine to create, there is no additional camshaft sensor requirement.

This object is achieved by the subject of Claim 1 solved, that is, by a device for cylinder detection in an internal combustion engine with a crankshaft sensor device for detecting a crank angle and one predetermined crankshaft position and output corresponding Crank signals; an ignition device for igniting the respective Cylinder of the internal combustion engine by generating corresponding ones High voltage pulses in response to corresponding control signals; a control device for receiving the crank signals and outputting the control signals to the ignition device in dependence of at least the crank signals; being the control device is designed so that it is in a Cylinder detection phase when receiving a crank signal accordingly a predetermined crank position a control signal for generating a high voltage pulse with a predetermined one achievable amplitude in at least one particular cylinder issues; an ignition detection device for detecting whether and / or or at which ignition voltage the particular cylinder through the High voltage pulse has been fired and outputting a corresponding one Ignition detection signal, and a cylinder detection device to determine whether the particular cylinder in the predetermined crank position in its stroke is based on at least the ignition detection signal.

This object is also achieved by the one specified in claim 25 Method solved, that is, by a method for cylinder detection in an internal combustion engine with the steps: detecting one Crank angle and a predetermined crankshaft position and Outputting corresponding crank signals; Generate a high voltage pulse with a predetermined achievable amplitude in at least one particular cylinder when capturing one predetermined crank position during a cylinder detection phase; Detect whether and / or at which ignition voltage the certain cylinders have been fired by the high voltage pulse and outputting a corresponding ignition detection signal; and Determine whether the particular cylinder is in the predetermined crank position is in his work cycle based at least the ignition detection signal.

Preferred developments are the subject of the dependent claims.

The principle of the present invention is based on the fact that Ignition voltage at a predetermined crank position, which on or near the TDC of the cylinder in question depends on the pressure prevailing in the cylinder. So is the ignition voltage at 1 bar typically 5 kV, while at about 5-7 bar is typically about 13-20 kV. The listed Pressures and ignition voltages can differ in two Adjust the cylinders of an engine when the a cylinder just at or near the TDC of its exhaust stroke (Valves are open) and the other cylinder is at or near the TDC of its work cycle (valves are closed) located.

Therefore, by detecting the different ignition voltages determine which of the cylinders is the one in the work cycle and the ignition sequence is determined accordingly be without the need for the usual camshaft sensor.

Firstly, there is the possibility of recording, that the high voltage pulse supplied in the cylinder detection phase is a normal high voltage pulse, i.e. a high voltage pulse, whose amplitude is that for ignition in the work cycle necessary size of typically about 13 kV can reach. In this case, the actual ignition voltage is detected and that Result for cylinder recognition evaluated.

Second, the one supplied in the cylinder detection phase High voltage pulse be a reduced high voltage pulse i.e. a high voltage pulse, the amplitude of which is for ignition size of typically about 13 kV required in the work cycle cannot reach, but only a size that is typical Is 7 kV and is sufficient for ignition in the exhaust cycle. In In this case, it is determined whether a spark has occurred at all and the result for cylinder detection is evaluated.

Once the initial order of the cylinders has been determined, so all further ignition times can be made up to the next one The motor stops incrementally by detecting the crank position fix with the crank sensor. In other words The cylinder detection only has to be done during the engine start-up phase be performed. Particularly advantageous on the subject Claim 1 of the present invention is therefore the fact that the usual camshaft sensor can be saved.

According to the preferred development according to claim 3, the predetermined crank position the top dead center of the particular Cylinders. This has the advantage that this Crank position the pressure difference between the work cycle and the exhaust cycle and thus the reliability of the measurement greatest is.

According to the further preferred development according to claim 4 the predetermined amplitude is smaller than that for ignition in the work cycle necessary amplitude. This has the advantage yourself that no additional tax expense for hiring Size of the amplitude of the high voltage pulses is necessary. In In this case, the ignition detection device is preferably such designed to have the ignition voltage of the particular cylinder detected. The ignition detection signal is then either the detected one Ignition voltage itself or a signal that can be clearly derived from it.

According to the further preferred development according to claim 6 the cylinder detection device has a storage device for storing at least one ignition reference signal and a comparison device to compare the ignition detection signal with the ignition reference signal. The ignition reference signal is preferred a reference voltage value which is chosen so that it is lower than the voltage amplitude necessary for ignition if the cylinder in question is in the work cycle, but higher than the voltage amplitude required for ignition if this cylinder is in the exhaust stroke. The ignition reference signal can e.g. B. 9 kV. This training is easy to realize, however, presupposes that the necessary for the ignition Ignition voltage in the compressed and in the uncompressed state is sufficiently different for reliable cylinder detection to enable.

According to the further preferred development according to claim 7 a plurality of ignition reference signals in the memory device according to different operating states of the internal combustion engine stored, and the comparison device is such designed to be the current operating state of the internal combustion engine corresponding ignition reference signal for comparison draws in. With such a configuration, the fact Are taken into account that the ignition reference signal from the operating state of the engine. Under operating condition are both internal parameters such as Compression pressure, as well as external parameters, e.g. Outside temperature or air pressure, to understand.

According to the further preferred development according to claim 8 designed the Zünderfassungseinrichtinng so that they the Ignition voltage of the particular cylinder for two consecutive ones Periods of the ignition alternating voltage are recorded. In this case the cylinder detection device preferably has a storage device for storing the first ignition detection signal and a comparison device for comparing the first ignition detection signal with the second ignition detection signal. If the first ignition detection signal represents a higher ignition voltage, is the particular cylinder at the first revolution in Work cycle, otherwise at the second rotation.

According to the further preferred development according to claim 10 is the ignition detection device is designed such that it the ignition voltage of at least two corresponding corresponding Cylinders at the same period of the alternating ignition voltage detected. In this case, the cylinder recognition device preferably a comparison device for comparing the Ignition detection signals corresponding to the two specific cylinders on. The simultaneous application of the ignition voltage to the two specific cylinder and the subsequent comparison of the detection signals has the advantage that the other influencing variables, the influence the ignition voltage, e.g. Electrode gap, gas composition and gas dynamics, in both cylinders usually are the same and therefore compensate each other.

According to the further preferred development according to claim 12 is the predetermined amplitude, i.e. H. the ignition reference signal, less than the amplitude required for ignition in the work cycle.

Such a reduced amplitude can be achieved, for example, by Reducing the energy supplied to the ignition coil on the primary side, specifically the primary current, or by reducing the slope the switch-off edge of the primary current.

In this case, the predetermined amplitude is preferably the ignition reference signal is higher than that for ignition in the exhaust stroke necessary amplitude.

In such a development, the ignition detection device preferably designed such that it detects whether the certain cylinders have been ignited, i.e. a YES / NO determination carries out.

According to the further preferred development according to claim 18 is the ignition device for generating bipolar high-voltage pulses designed. In addition to the training courses listed above, preferably in a unipolar ignition device can be realized with such a bipolar Ignition device further advantageous possibilities for cylinder detection.

According to the further preferred development according to claim 19 the control device is designed such that it has a control signal to generate a bipolar high voltage pulse with a different first and second predetermined amplitude outputs depending on the respective half-wave. In other words, the positive aspects of this training are and the negative half wave of the ignition voltage is different dimensioned.

In this case, the second predetermined amplitude is preferred the amplitude necessary for ignition in the work cycle, and the first predetermined amplitude less than the second predetermined Amplitude and higher than that necessary for ignition in the exhaust stroke Amplitude. It is also possible in this case that the Control device is designed such that it is the first predetermined Amplitude in successive periods of Ignition alternating voltage of a spark increases until the predetermined one Amplitude higher than that required for ignition in the exhaust cycle Amplitude is.

According to the further preferred development according to claim 23 the ignition detection device is designed such that it detects whether the particular cylinder in the first and / or second Half wave has been ignited. Will the particular cylinder already ignited in the first half-wave, it is in the exhaust stroke, otherwise he is in the work cycle.

According to the further preferred development according to claim 23 is the ignition detection device on the primary winding the respective ignition coil. Advantageous in this configuration is that it is easily possible to determine the timing of the Detect occurrence of an ignition spark on the primary side and from this the desired information about the pressure conditions in the win certain cylinder or its current stroke.

According to the further preferred development according to claim 24 is a start signal generator for generating a Starting signal when starting the engine and output the start signal to the control device for setting the Cylinder detection phase provided. This is an advantage because as already mentioned, the cylinder detection only at the beginning of the Operation of the engine is necessary. For example, the start signal with the starting position of the ignition key.

In the following, the present invention will be more preferred based on Embodiments with reference to the accompanying drawings are explained in more detail.

Fig. 1

eine schematische Darstellung einer bevorzugten Ausführungsform der erfindungsgemäßen Zylindererkennungsvorrichtung,

Fig. 2

eine schematische Darstellung des Zündspannungsverlaufs der Zündwechselspannung bei der Ausführungsform der erfindungsgemäßen Zylindererkennungsvorrichtung gemäß Fig. 1 während einer vollen Periode der Zündwechselspannung, in den Zylindern 1 und 4, wobei Zylinder 4 zündet, und

Fig. 3

eine ähnliche Darstellung des Zündspannungsverlaufs wie in Fig. 2, allerdings wird sowohl im Zylinder 1 und 4 ein Zündfunke erzeugt, jedoch zu unterschiedlichen Zeitpunkten, was ausgewertet wird.

The figures show:

Fig. 1

1 shows a schematic representation of a preferred embodiment of the cylinder detection device according to the invention,

Fig. 2

a schematic representation of the ignition voltage curve of the ignition alternating voltage in the embodiment of the cylinder detection device according to the invention according to FIG. 1 during a full period of the alternating ignition voltage, in cylinders 1 and 4, cylinder 4 igniting, and

Fig. 3

a similar representation of the ignition voltage curve as in Fig. 2, however, an ignition spark is generated in cylinders 1 and 4, but at different times, which is evaluated.

In the figures, identical reference symbols designate the same or functionally identical components.

Fig. 1 shows a schematic representation of a first preferred Embodiment of the cylinder detection device according to the invention.

In Fig. 1, reference numerals 1, 2, 3 and 4 denote a first, second, third and fourth cylinders of a four-cylinder four-stroke engine, which have a respective piston 10, 20, 30, and 40 included, which has a corresponding connecting rod 11, 21, 31 and 41 is connected to a crankshaft 15. The crankshaft 15 is by associated bearings 15a - 15e in the not shown Engine block stored.

There is one in the cylinder head of each cylinder 1, 2, 3 and 4 respective spark plugs 51, 52, 53 and 54 provided which the necessary ignition voltage from a corresponding ignition coil 61, 62, 63 and 64 is supplied.

With the primary side of a respective ignition coil 61, 62, 63 and 64 an associated ignition output stage 71, 72, 73 and 74 is connected, which for supplying and switching off the primary alternating current Ignition coils 61, 62, 63 and 64 can be controlled.

For this purpose, the ignition output stages 71, 72, 73 and 74 are via respective Control lines 81, 82, 83 and 84, the ignition voltage and / or Set the ignition current with a primary current source, not shown, which is expediently located in a control unit 100 is connected. The primary power source comes with a supply voltage of typically 12 V corresponding to the battery voltage operated.

The control unit 100 also delivers via control lines 91, 92, 93 and 94 control signals to the respective ignition output stages 71, 72, 73 and 74 to determine the duration and thus the beginning and the end to control the primary current supplied to the respective ignition coil. In this context, expressly for the purpose of Disclosure to the previously published EP 0 596 471 A1 by the applicant referenced, in which the control is already detailed of the ignition coils with determining the ignition energy and the ignition duration Signals is disclosed.

The first ignition output stage 71 corresponding to the first cylinder 1 and the ignition output stage 74 corresponding to the fourth cylinder 4 each have a primary-side ignition detection device in Form of a device, not shown, which is used to detect, whether and / or at which ignition voltage the relevant one first and fourth cylinders 1, 4 by a generated high voltage pulse has been ignited and issued a corresponding Ignition detection signal is used. The device can e.g. a primary-side time measuring device or a di / dt measuring device be. The corresponding ignition detection signals are sent to the control unit 100 supplied via signal lines 171 and 174.

A crankshaft sensor 25 is also located on the crankshaft 15 attached with the crank position and the common upper Dead center of the first and fourth cylinders 1, 4 can be detected can. A corresponding crank signal is sent to control unit 100 supplied via a signal line 125.

Finally 150 denotes a plurality of further signal lines, which supply corresponding signals to the control device 100, the operating state of the engine, e.g. Temperature, speed, Characterize the position of the ignition key, etc.

The following is the operation of the cylinder detection device thus constructed explained in more detail.

A so-called cylinder detection phase is determined by the starting position of the ignition key defines the control unit 100 communicated one of the signal lines 150. When receiving a Crank signal corresponding to the common crank position OT des first and fourth cylinders 1, 4 via the signal line 125 the control unit generates during this cylinder recognition phase 100, a control signal for generating a high voltage AC pulse with an amplitude of z. B. about 9 kV for the first and fourth ignition output stages 71, 74.

The amplitude of 9 kV of the high voltage pulse is chosen that it is less than the amplitude necessary for ignition, if the first or fourth cylinder 1, 4 in the work cycle located, but higher than the amplitude required for ignition, when the first and fourth cylinders 1, 4 are in the exhaust stroke is located.

Accordingly, in that of the two cylinders 1, 4, which is in the work cycle (here cylinder 1), none Spark generated, and in the one who is in the exhaust stroke is located (here the cylinder 4), an ignition spark Z is generated.

The primary detection devices provided in the first and fourth ignition output stage 71, 74 detect whether the associated Cylinder 1, 4 have been ignited by the high voltage pulse and deliver a corresponding ignition detection signal via the respective control line 171, 174 to the control device 100.

Based on the waveform of the ignition detection signal thus received the control unit determines with the help of an internal computer, which of the two cylinders 1, 4 is in its working cycle (in shown case of the cylinder 1) and hits a corresponding one Assignment as "cylinder one" for further ignition timing.

2 shows a representation of the ignition voltage curve according to FIG the illustrated embodiment of the cylinder detection device according to the invention of Fig. 1st

2 shows the time on the abscissa while on the ordinate is the secondary voltage on the spark plug 51, 54 of the first and fourth cylinders 1, 4 is shown. It should be noted that the abscissa is divided and always for the first Cylinder 1 and the fourth cylinder 4 the same time Represents process.

The secondary voltage curve of the first cylinder 1 begins with a negative range of approx. -3 kV, which comes from switching on the ignition output stage 71 and not interested here.

When the common crank position OT of the first and fourth cylinders 1, 4 is detected, the primary current of the ignition output stage 71 is switched off with a steep flank, and accordingly a high-voltage pulse with an achievable amplitude u of approx. 9 kV is generated by u = L di / dt is given. L denotes the mutual inductance of the ignition coil 61 and di / dt the time derivative of the current profile at the time the primary current is switched off in the relevant ignition output stage. Top dead center of a cylinder is to be understood here.

From relation (1) it can be seen that the size of the achievable Amplitude u of the high-voltage pulse on the one hand by reducing the steepness of the switch-off edge and on the other hand can be influenced by reducing the switch-off current is.

Since in the present case the achievable amplitude u of the high-voltage pulse not to ignite the one in the work cycle the first cylinder 1 is sufficient, the secondary voltage curve shows a short plateau at 9 kV and falls then off again.

The secondary voltage curve shown on the right in FIG. 2 is different of the fourth cylinder 4. The high-voltage pulse also begins here with the negative section of no interest, however, it only shows an increase up to at OT to about 5 kV, where a spark forms prematurely in cylinder 4, since this is in the ejection stroke. The one associated with the spark Ionization causes the voltage to drop to one so-called burning plateau at approx. 1 kV, which lasts until turns off the power amplifier. The secondary voltage then occurs the spark plug 64 again.

It should be noted that it is possible instead of the simultaneous detection of the voltage curve in the first and in the fourth cylinder 1, 4 a detection of the voltage curve in both or in only one of these cylinders in two consecutive Revolutions of the crankshaft, because the shown voltage curves in each of the cylinders in this Form of the primary-side control occur alternately.

A further embodiment is described below in connection with FIG. 3 of the present invention.

The spark plugs 51, 52, 53 are also in this embodiment and 54, the ignition coils 61, 62, 63 and 64, the ignition output stages 71, 72, 73 and 74 and the control device 100 for generating bipolar High voltage pulses designed. There is a high voltage pulse e.g. B. from a negative first half-wave and a positive second half-wave, which both in normal operation to generate an ignition spark.

Operation of the cylinder detection device thus constructed proceeds as follows.

During the cylinder detection phase, which is analogous to the above lets set the first embodiment, the amplitudes of positive and negative half wave made different sizes.

The first negative half-wave is dimensioned in such a way that they are in the compressed first working cycle Cylinder 1 does not lead to spark formation. The the second positive half-wave, on the other hand, receives the amplitude as with normal ignition process: thus only the second positive half-wave generate the ignition spark in the first cylinder 1.

Correspondingly, the fourth cylinder 4 becomes when such one is put on bipolar high voltage pulse already at the first ignited negative half wave.

The cylinder detection by the cylinder detection devices in the first and fourth ignition output stages 71, 74, that the respective cylinder detection device detects whether the relevant cylinders in the first and / or second half-wave has been ignited.

Claims (25)

Device for cylinder detection in an internal combustion engine with: a crankshaft sensor device for detecting a crank angle and a predetermined crankshaft position and outputting corresponding crank signals; an ignition device for igniting the respective cylinders of the internal combustion engine by generating corresponding high-voltage pulses in response to corresponding control signals; a control device for receiving the crank signals and outputting the control signals to the ignition device as a function of at least the crank signals;
the control device being designed in such a way that, in a cylinder detection phase, when it receives a crank signal corresponding to a predetermined crank position, it outputs a control signal for generating a high-voltage pulse with a predetermined achievable amplitude in at least one specific cylinder; an ignition detection device for detecting whether and / or at which ignition voltage the particular cylinder has been ignited by the high-voltage pulse and outputting a corresponding ignition detection signal; and a cylinder detection device for determining whether the specific cylinder is in the predetermined crank position in its work cycle based on at least the ignition detection signal. Device for cylinder detection according to one of the preceding Claims, characterized in that the ignition detection device on the primary winding of the respective Ignition coil is provided. Device for cylinder detection according to claim 1 or 2, characterized in that the predetermined crank position at least approximately the top dead center of the particular cylinder is. Device for cylinder detection according to one of the claims 1 to 3, characterized in that the predetermined amplitude smaller than the amplitude required for ignition in the work cycle is. Device for cylinder detection according to claim 4, characterized characterized in that the ignition detection device is designed in this way is that they have the ignition voltage of the particular cylinder detected. Device for cylinder detection according to claim 5, characterized characterized in that the cylinder detection device a Storage device for storing at least one ignition reference signal and a comparison device for comparing the Has ignition detection signal with the ignition reference signal. Device for cylinder detection according to claim 5, characterized characterized in that a plurality in the storage device of ignition reference signals according to different operating states the internal combustion engine are stored and the comparison device is designed to match the current one Corresponding operating state of the internal combustion engine Ignition reference signal is used for comparison. Device for cylinder detection according to one of the claims 1 to 4, characterized in that the ignition detection device is designed so that it the ignition voltage of the certain cylinders in two consecutive periods detected. Device for cylinder detection according to claim 8, characterized characterized in that the cylinder detection device a Storage device for storing the first ignition detection signal and a comparison device for comparing the first ignition detection signal with the second ignition detection signal having. Device for cylinder detection according to one of the claims 1 to 4, characterized in that the ignition detection device is designed so that it the ignition voltage at least two corresponding corresponding cylinders same rotation of the crankshaft detected. Device for cylinder detection according to claim 10, characterized characterized in that the cylinder detection device a comparison device for comparing the ignition detection signals corresponding to the two particular cylinders. Device for cylinder detection according to one of the claims 1 to 3, characterized in that the predetermined amplitude less than the amplitude required for ignition in the work cycle is. Device for cylinder detection according to claim 12, characterized characterized in that the predetermined amplitude is higher than is the amplitude necessary for ignition in the exhaust stroke. Device for cylinder detection according to claim 12, characterized characterized in that the control device is designed in this way is that it has the predetermined amplitude in successive Periods of the crankshaft increased until the predetermined Amplitude higher than that for ignition in the exhaust stroke is necessary amplitude. Device for cylinder detection according to claim 13 or 14, characterized in that the ignition detection device is designed to detect whether the particular cylinder has been ignited. Device for cylinder detection according to claim 13 or 14, characterized in that the ignition detection device is designed so that in two consecutive periods the crankshaft detects whether the particular cylinder is fired has been. Device for cylinder detection according to claim 13 or 14, characterized in that the ignition detection device is designed so that it detects whether one of at least two corresponding cylinders ignited has been. Device for cylinder detection according to one of the preceding Claims, characterized in that the ignition device designed to generate bipolar high-voltage pulses is. Device for cylinder detection according to claim 18, characterized characterized in that the control device is designed in this way is that it is a control signal for generating a bipolar High voltage pulse with a different first and second predetermined amplitude depending on the respective Outputs half wave. Device for cylinder detection according to claim 19, characterized characterized in that the second predetermined amplitude the amplitude necessary for ignition in the work cycle and the first predetermined amplitude is less than the second predetermined Amplitude is. Device for cylinder detection according to claim 20, characterized characterized in that the first predetermined amplitude higher than the amplitude required for ignition in the exhaust stroke is. Device for cylinder detection according to claim 20, characterized characterized in that the control device is designed in this way is that it has the first predetermined amplitude in successive Revolutions of the crankshaft increased until the predetermined amplitude higher than that for ignition in the exhaust stroke is necessary amplitude. Device for cylinder detection according to claim 21 or 22, characterized in that the ignition detection device is designed to detect whether the particular cylinder have been ignited in the first and / or second half-wave is. Device for cylinder detection according to one of the preceding Claims, characterized in that a starting signal generating device for generating a start signal when starting the internal combustion engine and outputting the starting signal to the control device for determining the cylinder detection phase is provided. Method for cylinder detection in an internal combustion engine with the steps: Detecting a crank angle and a predetermined crankshaft position and outputting corresponding crank signals; Generating a high-voltage pulse with a predetermined achievable amplitude in at least one specific cylinder when detecting a predetermined crank position during a cylinder detection phase;
Detecting whether and / or at which ignition voltage the particular cylinder has been ignited by the high-voltage pulse and outputting a corresponding ignition detection signal; and Determine whether the particular cylinder is in the predetermined crank position in its stroke based on at least the ignition detection signal.

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