Control circuit for dormancy and awakening of electronic brake control unit
1. A control circuit for sleep and wake-up of an electronic brake control unit, comprising:
one controlled end circuit and at least two control end circuits;
the controlled end circuit is arranged on a power panel in the electronic brake control unit, and the control end circuit is arranged on at least two different control board cards in the electronic brake control unit;
the control end circuit outputs a continuous high level signal, a continuous low level signal, a frequency signal or a power supply control signal in a high resistance state according to the state of an external sleep instruction; when the controlled end circuit receives the frequency signal which is sent by the control end circuit and exceeds the frequency threshold, the controlled end circuit outputs a closing signal to the power supply module to close the power supply, and the electronic brake control unit enters a dormant state to realize dormant control; otherwise, the controlled end circuit outputs a starting signal to the power supply module, the power supply is started, and the electronic brake control unit realizes awakening control.
2. The control circuit of claim 1, wherein when the external sleep command is a valid external sleep command, one of the control end circuits outputs a frequency signal exceeding a frequency threshold to the controlled end circuit, the other of the control end circuits outputs the high impedance state to the controlled end circuit, and the controlled end circuit outputs the shutdown signal; when the external sleep command is an invalid external sleep command, one of the control end circuits outputs a continuous high level signal, a continuous low level signal or a frequency signal lower than the frequency threshold to the controlled end circuit, the other of the control end circuits outputs a high impedance state to the controlled end circuit, and the controlled end circuit outputs the start signal.
3. The control circuit of claim 2, further comprising:
the power supply module outputs a power supply enabling control state through the state feedback circuit;
the state detection circuit receives and detects the power supply enabling control state;
and the power supply detection circuit is used for detecting the voltage of the power supply module.
4. The control circuit of claim 3, wherein the status feedback circuit is disposed on the power board, and the status detection circuit and the power supply detection circuit are disposed on the control board.
5. The control circuit according to claim 4, wherein the control board is further provided with a controller capable of performing information interaction through communication, and the controller is connected to the control end circuit, the state detection circuit, and the power supply detection circuit, respectively, and configured to receive the external sleep command and control the control end circuit to output the continuous high level signal, the continuous low level signal, the frequency signal, or the high impedance state according to a state of the external sleep command.
6. The control circuit of claim 5, wherein the power supply module controls an output power voltage by the turn-on signal sent by the controlled terminal, and the turn-off signal sent by the controlled terminal controls a stop of the output power voltage.
7. The control circuit of claim 6, wherein the power enable control state is a switching value signal, wherein one level indicates that power sleep control is active and another level indicates that power sleep control is inactive.
8. The control circuit according to claim 7, wherein after the wake-up control is finished, if the power enable control state collected by the state detection circuit indicates that power sleep control is valid and the power voltage of the power supply module collected by the power supply detection circuit is abnormal, the controller determines that the wake-up control is abnormal; after the sleep control is finished, if the power supply enabling control state collected by the state detection circuit shows that the power supply sleep control is invalid and the power voltage of the power supply module collected by the power supply detection circuit is normal, the controller judges that the sleep control is abnormal.
9. The control circuit according to claim 8, wherein when the wake-up control is abnormal, the control end circuit forcibly pulls the level of the power control signal high or low, so that the controlled end circuit outputs the start signal to control the power supply module to start the power supply, the electronic brake control unit wakes up from a sleep state and enters a normal operating state, and the controller sends the wake-up control abnormality to the train network system through the external communication circuit for prompting.
10. The control circuit according to claim 8, wherein when the sleep control is abnormal, the controller sends the sleep control abnormality to the train network system through the external communication circuit to prompt.
Background
The brake system is a key system of a rail transit vehicle, rail vehicles such as a motor car, a passenger car and a freight car have requirements on the power consumption of the brake system, and under the working conditions that the pantograph is not lifted and the storage battery is only used, the brake system is required to be in a dormant state in order to prevent the storage battery from being under-voltage, namely, only the key signal detection function is reserved, and other functions are all in a closed state. And after the vehicle rises to be connected with high voltage, the braking system needs to be immediately awakened, namely all functions are all put into a normal working state.
The electronic brake control unit is internally provided with two power supplies, wherein one power supply is a control power supply for supplying power to chips such as a CPU (central processing unit), a storage chip, a communication chip and the like, and is generally DC5V or DC3.3V; the other is a power supply for supplying power to the sensor, the solenoid valve and the relay, which is generally DC24V or DC 12V. The conventional sleep wake-up function is mainly implemented by turning off or enabling the output of the driving power module by sending a high/low level signal by the CPU. For example, when the CPU detects that sleep is required, it sends a high level signal to control the DC24V power module to turn off, thereby achieving the purpose of reducing power consumption; when the CPU detects that the electronic brake control unit needs to be awakened, the CPU sends a low level signal to control the DC24V power supply module to normally supply power, so that all functions of the electronic brake control unit are put into use.
The brake system is a key system of the rail transit vehicle, the electronic brake control unit is a core control component of the brake system, and if the dormancy and awakening functions of the electronic brake control unit are abnormal, especially the fault that the electronic brake control unit cannot be awakened occurs, the brake control function is disabled, and the safe operation of the train is seriously influenced.
The current control method has the following defects:
(1) the high/low level signal control is adopted, the signal is easy to cause control errors due to the problems of interference and the like, the fault guidance is uncertain, and the electronic brake control unit cannot be awakened.
(2) And the state feedback is not available, the monitoring diagnosis is not available, and if the abnormality occurs, the vehicle cannot obtain the state and cannot perform related operations.
(3) The control can be carried out only by a single CPU, and if the CPU is abnormal, the sleep or awakening cannot be carried out.
Disclosure of Invention
The invention provides a control circuit for sleeping and waking up an electronic brake control unit, aiming at the technical problems that errors are easy to occur in sleeping and waking up of the control unit and a monitoring mechanism is incomplete.
The embodiment of the application provides a control circuit that electronic brake control unit dormancy and awaken up, includes:
one controlled end circuit and at least two control end circuits;
the controlled end circuit is arranged on a power panel in the electronic brake control unit, and the control end circuit is arranged on at least two different control board cards in the electronic brake control unit;
the control end circuit outputs a continuous high level signal, a continuous low level signal, a frequency signal or a power supply control signal in a high resistance state according to the state of an external sleep instruction; when the controlled end circuit receives the frequency signal which is sent by the control end circuit and exceeds the frequency threshold, the controlled end circuit outputs a closing signal to the power supply module to close the power supply, and the electronic brake control unit enters a dormant state to realize dormant control; otherwise, the controlled end circuit outputs a starting signal to the power supply module, the power supply is started, and the electronic brake control unit realizes awakening control.
In the above control circuit, when the external sleep command is an effective external sleep command, one of the control end circuits outputs a frequency signal exceeding a frequency threshold to the controlled end circuit, the other of the control end circuits outputs the high impedance state to the controlled end circuit, and the controlled end circuit outputs the shutdown signal; when the external sleep command is an invalid external sleep command, one of the control end circuits outputs a continuous high level signal, a continuous low level signal or a frequency signal lower than the frequency threshold to the controlled end circuit, the other of the control end circuits outputs a high impedance state to the controlled end circuit, and the controlled end circuit outputs the start signal.
The control circuit further includes:
the power supply module outputs a power supply enabling control state through the state feedback circuit;
the state detection circuit receives and detects the power supply enabling control state;
and the power supply detection circuit is used for detecting the voltage of the power supply module.
In the above control circuit, the state feedback circuit is disposed on the power board, and the state detection circuit and the power supply detection circuit are disposed on the control board.
The control circuit is characterized in that controllers capable of performing information interaction through communication are respectively arranged on the control board cards, the controllers are respectively connected with the control end circuit, the state detection circuit and the power supply detection circuit and used for receiving the external sleep instruction and controlling the control end circuit to output the continuous high-level signal, the continuous low-level signal, the frequency signal or the high-resistance state according to the state of the external sleep instruction.
In the above control circuit, the power supply module controls the output power voltage according to the start signal sent by the controlled terminal, and the stop signal sent by the controlled terminal controls the stop of the output power voltage.
The power supply enable control state is a switching value signal, wherein one level indicates that the power supply sleep control is effective, and the other level indicates that the power supply sleep control is ineffective.
In the above control circuit, after the wake-up control is finished, if the power enable control state acquired by the state detection circuit indicates that the power sleep control is valid and the power voltage of the power supply module acquired by the power supply detection circuit is abnormal, it is determined that the wake-up control is abnormal by the controller; after the sleep control is finished, if the power supply enabling control state collected by the state detection circuit shows that the power supply sleep control is invalid and the power voltage of the power supply module collected by the power supply detection circuit is normal, the controller judges that the sleep control is abnormal.
When the wake-up control is abnormal, the control end circuit forcibly pulls the level of the power supply control signal high or low to enable the control end circuit to output the starting signal to control the power supply module to start the power supply, the electronic brake control unit wakes up from a dormant state to enter a normal working state, and the controller sends the wake-up control abnormality to the train network system through the external communication circuit to prompt.
In the control circuit, when the sleep control is abnormal, the controller sends the abnormal sleep control to the train network system for prompting through the external communication circuit.
Compared with the prior art, the invention has the advantages and positive effects that:
1. the output and the closing of the power supply module are controlled by changing high/low level signals into frequency signals, so that the reliability of the dormancy and awakening functions of the electronic brake control unit is effectively improved, and the fault occurrence probability is reduced;
2. the system has a state feedback and fault detection mechanism, if the system is awakened abnormally, internal redundancy control is carried out, the system can quit the sleep by forcibly pulling the level high or low, a fault is reported, and a driver or a maintenance worker is prompted to carry out inspection through a train network system.
Drawings
FIG. 1 is a schematic diagram of a control circuit framework for sleep and wake-up of an electric brake control unit according to the present invention;
FIG. 2 is a schematic structural diagram of an electric brake control unit according to an embodiment of the present disclosure;
fig. 3 is a schematic diagram of a power enable control circuit on a power board according to the present invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be described and illustrated below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments provided in the present application without any inventive step are within the scope of protection of the present application.
It is obvious that the drawings in the following description are only examples or embodiments of the present application, and that it is also possible for a person skilled in the art to apply the present application to other similar contexts on the basis of these drawings without inventive effort. Moreover, it should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another.
Reference in the specification to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the specification. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of ordinary skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments without conflict.
Unless defined otherwise, technical or scientific terms referred to herein shall have the ordinary meaning as understood by those of ordinary skill in the art to which this application belongs. Reference to "a," "an," "the," and similar words throughout this application are not to be construed as limiting in number, and may refer to the singular or the plural. The present application is directed to the use of the terms "including," "comprising," "having," and any variations thereof, which are intended to cover non-exclusive inclusions; for example, a process, method, system, article, or apparatus that comprises a list of steps or modules (elements) is not limited to the listed steps or elements, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus. Reference to "connected," "coupled," and the like in this application is not intended to be limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. The term "plurality" as referred to herein means two or more. "and/or" describes an association relationship of associated objects, meaning that three relationships may exist, for example, "A and/or B" may mean: a exists alone, A and B exist simultaneously, and B exists alone. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship. Reference herein to the terms "first," "second," "third," and the like, are merely to distinguish similar objects and do not denote a particular ordering for the objects.
The present invention is described in detail with reference to the embodiments shown in the drawings, but it should be understood that these embodiments are not intended to limit the present invention, and those skilled in the art should understand that functional, methodological, or structural equivalents or substitutions made by these embodiments are within the scope of the present invention.
Before describing in detail the various embodiments of the present invention, the core inventive concepts of the present invention are summarized and described in detail by the following several embodiments.
Two paths of power supplies are arranged inside the Electronic Brake Control Unit (EBCU) and are respectively a control power supply and a power supply, the power supply with larger power is controlled to be cut off during sleep, the power supply of the control power supply is reserved, and the sleep function is realized. The power supply is controlled to be turned off or output by using the frequency signal, so that the electronic control unit is dormant or awakened, and other board cards can acquire the voltage of the dormancy control feedback signal and the power supply in real time to monitor the state and diagnose the fault while one board card is in dormancy or awakening control.
Example (b):
fig. 1 is a schematic diagram of a control circuit framework for sleep and wake-up of an electronic brake control unit according to the present invention. Referring to fig. 1, this embodiment discloses an embodiment of a control circuit for sleep and wake of an electronic brake control unit.
The control circuit provided by the invention comprises a controlled end circuit and at least two control end circuits;
the controlled end circuit is arranged on a power panel in the electronic brake control unit, and the control end circuit is arranged on at least two different control board cards in the electronic brake control unit; the control board card comprises an interface board, a main control board, other board cards and the like.
The power panel is provided with a power supply module for outputting power voltage and a state feedback circuit, and the power supply module outputs a power supply enabling control state through the state feedback circuit;
be provided with on the control integrated circuit board and be used for receiving and detecting the state detection circuitry of power enable control state, be used for detecting the power supply detection circuitry of power supply module's voltage still is equipped with the controller that can carry out the information interaction through communication, the controller is connected respectively control end circuit state detection circuitry and power supply detection circuitry for receive outside dormancy instruction, and according to the state control of outside dormancy instruction control end circuit output last high level signal last low level signal frequency signal or high resistance state.
When the external sleep instruction is an effective external sleep instruction, one of the control end circuits outputs a frequency signal exceeding a frequency threshold to the controlled end circuit, the other of the control end circuits outputs a high-impedance state to the controlled end circuit, the controlled end circuit outputs a closing signal to the power supply module, the power supply is closed, and the electronic brake control unit enters a sleep state to realize sleep control;
after the sleep control is finished, if the power supply enabling control state collected by the state detection circuit shows that the power supply sleep control is invalid and the power voltage of the power supply module collected by the power supply detection circuit is normal, the controller judges that the sleep control is abnormal. And when the sleep control is abnormal, the controller sends the abnormal sleep control to the train network system for prompting through the external communication circuit.
When the external sleep instruction is an invalid external sleep instruction, one of the control end circuits outputs a continuous high level signal, a continuous low level signal or a frequency signal lower than the frequency threshold value to the controlled end circuit, the other of the control end circuits outputs a high resistance state to the controlled end circuit, the controlled end circuit outputs an opening signal to the power supply module, the power supply is opened, and the electronic brake control unit realizes wake-up control.
After the wake-up control is finished, if the power supply enabling control state acquired by the state detection circuit shows that the power supply sleep control is effective and the power voltage of the power supply module acquired by the power supply detection circuit is abnormal, judging that the wake-up control is abnormal through the controller; when the wake-up control is abnormal, the control end circuit forcibly pulls the level of the power control signal up or down to enable the control end circuit to output the starting signal to control the power supply module to start the power supply, the electronic brake control unit wakes up from a dormant state to enter a normal working state, and the controller sends the wake-up control abnormality to the train network system through the external communication circuit to prompt.
The following describes in detail a specific embodiment of the control circuit for sleep and wake-up of the electronic brake control unit according to the present invention with reference to the following embodiments.
As shown in fig. 2, the Electronic Brake Control Unit (EBCU) has a chassis-board structure, and includes boards such as a power board, a main control board, an interface board, and a back board.
The power panel comprises two power modules from DC110V to DC5V and from DC110V to DC24V, namely a control power module and a power module, DC5V is a control power supply (also can be DC3.3V) of the EBCU and supplies power to chips such as a CPU (namely a controller) and communication of each board card, and DC24V is a power supply of the EBCU and supplies power to an external electromagnetic valve, a sensor and the like in addition to the electronic brake control unit. The DC 110V-to-DC 24V power supply module has an enabling function and can be controlled to output DC24V voltage or not.
The power strip also has a power enable control circuit (i.e., a controlled-end circuit) for outputting an enable signal (i.e., a start signal) for controlling the power module to be turned on or a turn-off signal for controlling the power module to be turned off. The main control board and the interface board are both provided with a power supply control circuit (namely a control end circuit) for outputting a power supply control signal, and the power supply control circuit is connected with a power supply enabling control circuit on the power supply board through a backboard bus. The power control circuit is a tri-state output circuit, can output high level, low level and high impedance state, and outputs continuous high level signal, continuous low level signal, frequency signal or power control signal in high impedance state according to the received signal of the controller. In order to ensure the validity of the power control signal, one board card of the main control board or the interface board is responsible for outputting a frequency signal, and the other board card outputs a high-impedance state.
Fig. 3 is a schematic diagram of a power enable control circuit on a power board according to the present invention, as shown in fig. 3, a power control signal must be a frequency signal exceeding a certain frequency to turn on a collector and an emitter of a triode Q3, so as to drive an optocoupler U1 to turn on, and turn on an enable signal port of a 24V power module to a low level, at this time, no output is generated when the DC110V is converted into the DC24V power module; when the power control signal is at a high level or a low level, the triode Q3 is in a cut-off state, the output of the optocoupler U1 is turned off, the enable signal port is pulled up through the inside of the voltage module to be at a high level, and the DC110V is converted into the DC24V to be normally output by the power module.
The main control board and the interface board are both provided with state detection circuits, and can acquire the sleep control state displayed by the power supply enabling control state in real time. The power supply enable control state is a switching value signal, one level indicates that the power supply sleep control is effective, and the other level indicates that the power supply sleep control is ineffective.
The main control board and the interface board are both provided with a DC24V detection circuit (namely a power supply detection circuit), and can acquire the voltage of a DC24V power supply in real time.
The main control board receives a dormancy instruction (network dormancy instruction for short) sent by a train network system and sends the dormancy instruction to the internal communication bus, and the interface board obtains the state of a network signal of the dormancy instruction through the internal communication bus; the interface board collects the sleep command hard wire signal (hard wire sleep command for short) and sends the signal to the internal communication bus, and the main control board obtains the state of the sleep command hard wire signal through the internal communication bus. The external sleep command includes a network sleep command and/or a hard-wire sleep command.
Specifically, when the power control signal is a frequency signal and the frequency exceeds a certain value, the control end circuit can control the DC24V module not to output, and enter a sleep state; if the power control signal is high, low or the frequency is lower than a certain value, the control circuit controls the DC24V module to output normally, thereby exiting the sleep mode.
The power supply control signal can be controlled by a single board card or a plurality of board cards, and different dormancy/awakening control logics can be provided under different system function requirements. The present embodiment lists two representative vehicle system control methods and abnormality handling methods.
1. Vehicle system with both network sleep command and hard-wire sleep command
1.1 sleep control and exception handling
(1) Control strategy
When the network dormancy instruction and the hard wire dormancy instruction are effective at the same time, the electronic brake control unit is controlled to enter a dormancy state, otherwise, the electronic brake control unit does not enter the dormancy state.
(2) Control method
The main control board sends out a frequency signal through the power control circuit, the interface board outputs a high-resistance state, the power enable control circuit of the power module is controlled to output a closing signal, the 24V power module is controlled to be closed, no 24V power is output, and the electronic control unit enters a dormant state.
Meanwhile, the power supply module sends out a power supply enabling control state through the state feedback circuit, and the main control board and the interface board acquire the state for judging and processing the abnormity.
(3) Anomaly determination and handling
After the sleep control is performed for a period of time, if the collected power enable control state indicates that the sleep control feedback signal is invalid (indicating that the sleep control is not performed) and the collected DC24V voltage is normal, it is determined that the sleep control is abnormal.
The interface board reports the abnormity to the main control board through the internal communication bus, and the main control board sends the abnormity result and the judgment result of the interface board to the train network system through the external communication interface to prompt for checking. And (4) reporting the fault through the train network system for the diagnosed abnormal condition, and prompting a driver or a maintenance worker to carry out inspection.
1.2 Wake-Up control and Exception handling
(1) Control strategy
And when the network sleep command or the hard line sleep command is invalid, exiting the sleep state.
(2) Control method
The main control board stops sending frequency signals, outputs low level, controls the power supply enabling control circuit of the power supply module to output enabling signals, controls the 24V power supply module to be turned on, outputs 24V, and awakens the electronic control unit from a sleep state to enter a normal working state.
Meanwhile, the power supply module sends out a power supply enabling control state through the state feedback circuit, and the main control board and the interface board acquire the state for judging and processing the abnormity.
(3) Anomaly determination and handling
After the wake-up control is performed for a period of time, the collected power enable control state indicates that the sleep control feedback signal is still valid (indicating that the sleep control is being performed), and if no voltage is collected at DC24V, it is determined that the wake-up control is abnormal.
The interface board control pin outputs low level, pulls down the dormancy control signal by force, makes the power enable control circuit output enable signal, controls 24V power module to open, outputs 24V, the electronic control unit awakens from the dormancy state, enters into normal operating condition, the main control board sends the abnormality to the train network system through the external communication interface, prompts to check. If the train can not be awakened normally after a period of time, the main control board reports a higher-level fault code to the train network system through the external communication interface. And (4) reporting the fault through the train network system for the diagnosed abnormal condition, and prompting a driver or a maintenance worker to carry out inspection.
2. For vehicle system with hard wire sleep command and without network sleep command
2.1 sleep control and exception handling
(1) Control strategy
And when the hard wire sleep instruction is effective, controlling the electronic brake control unit to enter a sleep state, otherwise, not entering the sleep state.
(2) Control method
The interface board sends out a frequency signal through the power control circuit, the main control board outputs a high-resistance state at the same time, the power enable control circuit of the power module is controlled to output a closing signal, the 24V power module is controlled to be closed, no 24V power is output, and the electronic control unit enters a dormant state.
Meanwhile, the power supply module sends out a power supply enabling control state through the state feedback circuit, and the main control board and the interface board acquire the state for judging and processing the abnormity.
(3) Anomaly determination and handling
After the sleep control is performed for a period of time, if the collected power enable control state indicates that the sleep control feedback signal is invalid (indicating that the sleep control is not performed) and the collected DC24V voltage is normal, it is determined that the sleep control is abnormal.
The interface board reports the abnormity to the main control board through the internal communication bus, and the main control board sends the abnormity result and the judgment result of the interface board to the train network system through the external communication interface to prompt for checking. And (4) reporting the fault through the train network system for the diagnosed abnormal condition, and prompting a driver or a maintenance worker to carry out inspection.
2.2 Wake-Up control and Exception handling
(1) Control strategy
When the hard-wired sleep instruction is invalid, the sleep state is exited.
(2) Control method
The interface board stops sending frequency signals, outputs low level, controls a power supply enable control circuit of the power supply module to output enable signals, controls the 24V power supply module to be turned on, outputs 24V, and awakens the electronic control unit from a sleep state to enter a normal working state.
Meanwhile, the power supply module sends out a power supply enabling control state through the state feedback circuit, and the main control board and the interface board acquire the state for judging and processing the abnormity.
(3) Anomaly determination and handling
After the wake-up control is performed for a period of time, the collected power enable control state indicates that the sleep control feedback signal is still valid (indicating that the sleep control is being performed), and if no voltage is collected at DC24V, it is determined that the wake-up control is abnormal.
The main control board controls the pin to output a low level, forcibly pulls down the dormancy control signal, enables the power supply enabling control circuit to output an enabling signal, controls the 24V power supply module to be turned on, outputs 24V, wakes up the electronic control unit from the dormancy state, enters a normal working state, and simultaneously sends an abnormality to the train network system through the external communication interface to prompt for checking. If the train can not be awakened normally after a period of time, the main control board reports a higher-level fault code to the train network system through the external communication interface. And (4) reporting the fault through the train network system for the diagnosed abnormal condition, and prompting a driver or a maintenance worker to carry out inspection.
Specifically, while one board performs sleep/wake-up control, other boards can acquire the power enable control state in real time, and can acquire the voltage of the DC24V power supply in real time for state monitoring and fault diagnosis. If the abnormal awakening occurs, redundant control can be performed, the power supply of the DC24V is started by forcibly pulling the level high or low to quit the sleep, and the voltage of the DC24V power supply can be collected in real time and the brake system can work normally.
The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.
In summary, the invention provides a sleep and wake-up control circuit and a control method suitable for an electronic brake control unit of a rail vehicle, which can effectively improve the reliability of the sleep and wake-up functions of the electronic brake control unit, reduce the probability of fault occurrence, and have the functions of state feedback and fault detection.
The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.
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