DE102023100319A1 - ELECTRONIC VEHICLE CONTROL UNIT - Google Patents

Abstract

A first power supply circuit (5) sets and outputs a VB voltage to a first power supply voltage to operate a calculator (8). A switch (M1) is connected between a second input node (N2) receiving a BATT voltage and a first input node (N1) receiving the VB voltage. A switch control circuit turns the switch (M1) on and off. When the VB voltage falls below a predetermined first threshold voltage that reduces the first power supply voltage (Vo6) of the first power supply circuit (5) to lower than a predetermined output threshold voltage, the switching control circuit inputs the BATT voltage to the first input node (N1) by turning on the switch (M1). The first power supply circuit (5) sets the first power supply voltage (Vo6) to a power supply voltage value smaller than an output threshold voltage and outputs it for maintaining the operation of the calculator (8).

Description

technical field

The present invention relates to a vehicle electronic control unit.

State of the art

When an initialization command is issued, a computer performs various processing such as data backup after the initialization command is issued and before the computer is stopped. Therefore, it is necessary to continue supplying the computer with a voltage that guarantees the operation of the computer for a predetermined time (e.g., 2 µs) after the initialization command is issued.

Normally, when the computer executes processing before a reset, the computer uses a time of discharging an accumulated energy in a capacitor mounted in a power supply circuit. If such a conventional technique is used, it is not practical in terms of the cost and the mounting area of the capacitor because it is necessary to mount a large-capacity capacitor.

In the conventional configuration, since there is a dependency on the discharge time of the energy stored in the capacitor, the discharge time becomes shorter as the power consumption of the computer is larger. In recent years, due to a significant increase in power consumption of computers, it has become difficult to continue supplying power to the computer for a predetermined time or longer only by discharging the capacitor. The one in the JP H11- 266 547 A The technology described is relevant to the present application.

Prior Art Literature

patent document

JP H11- 266 547 A

Summary

Technical problem

It is an object of the present invention to provide a vehicle electronic control unit which enables a computer to reliably carry out processing before resetting even when the computer consumes a large amount of power.

means of solving the problem

According to the present invention, the operation is as follows. A first power supply circuit operates a computer based on setting a first voltage to a first power supply voltage and outputting the first power supply voltage. A switch is connected between a second input node for receiving a second voltage and a first input node for receiving the first voltage. The switch control circuit turns the switch on and off.

When the first voltage falls below a first threshold voltage that causes the first power supply voltage of the first power supply voltage to fall below a predetermined output threshold voltage, a switching control circuit inputs the second voltage to the first input node by turning on the switch. In addition, the first power supply circuit sets and outputs the first power supply voltage to a power supply voltage value lower than an output threshold voltage for maintaining operation of the computer. Thus, the operation of the computer can be maintained, and even if the power consumption of the computer increases, the processing before resetting can be reliably performed.

character list

• 1 14 is an electrical configuration block diagram of a vehicle electronic control unit according to a first embodiment;
• 2 Fig. 14 is a circuit configuration example of a power supply IC and a first power supply circuit;
• 3 Fig. 14 is a circuit configuration example of a second power supply circuit and a third power supply circuit;
• 4 Fig. 14 is a flowchart schematically showing an operation;
• 5 is a timing chart;
• 6 Fig. 14 is a timing chart of a comparative example; and
• 7 Fig. 12 is a timing chart for explaining the prior art technology.

Detailed description

Hereinafter, an embodiment of a vehicle electronic control unit will be described with reference to the drawings. 1 12 schematically shows an electrical configuration of the vehicle electronic control unit 1. The electronic control unit 1 inputs a VB voltage, which is a first voltage, to a first input node N1 via a VB terminal T1. The VB voltage is supplied from a vehicle battery 3 through a main relay 2 serving as a start switch for the vehicle. The VB voltage is a power source supplied as a main power source for the electronic control unit 1, and normally has a standard value of about 14V. In addition, the electronic control unit 1 inputs a BATT voltage, which is a second voltage that is constantly supplied from the vehicle battery 3, to a second input node N2 via a BATT terminal T2.

The electronic control unit 1 includes a power supply IC 4 (IC: integrated circuit or integrated circuit), a first power supply circuit 5, a second power supply circuit 6, a third power supply circuit 7, a computer or calculator 8 and an initialization command circuit 9. The first input node N1 is connected to the first power supply circuit 5, and the first power supply circuit 5 generates a first power supply voltage Vo6 based on the VB voltage from the first input node N1 is entered. The second power supply circuit 6 generates a second power supply voltage Vo5 to be supplied to the calculator 8 based on the first power supply voltage Vo6 of the first power supply circuit 5. The third power supply circuit 7 generates a third power supply voltage Vo1 to be supplied to the calculator 8 based on the first power supply voltage Vo6 of the first power supply circuit 5. As a result, the first power supply circuit 5 can power the calculator 8 by setting the VB voltage to the first power supply voltage Vo6 and off give the same operate.

The calculator 8 is formed by combining a processor, RAM, ROM, non-volatile memory, A/D conversion circuit, communication circuit (all are not shown), and so on, and performs predetermined vehicle control while power is supplied thereto. During shutdown, when the supply of the power supply voltage is cut off, the calculator 8 is designed to save data temporarily stored in the working memory of the RAM or the like in a non-volatile memory before stopping.

Also, the initialization instruction circuit 9 sends a reset signal INIT to the calculator 8 when the second power supply voltage Vo5 of the second power supply circuit 6 or the third power supply voltage Vo1 of the third power supply circuit 7 falls to an abnormal threshold voltage indicating an abnormality. When it is determined by monitoring the second power supply voltage Vo5 of the second power supply circuit 6 or the power supply voltage Vo1 of the third power supply circuit 7 that the power supply voltage of the calculator 8 becomes abnormal, the initialization command circuit 9 issues an initialization command to the calculator 8 and resets it, that is, initializes the calculator 8. In other words, the power supply voltages Vo5 and Vo1 are monitored, and when the power supply voltage of the calculator 8 is determined to be abnormal, the calculator 8 can reset be set.

Also, a switch M1 is connected between the second input node N2 for inputting the BATT voltage and the first input node N1 for inputting the VB voltage. The switch M1 is a MOSFET and can switch on and off a current conduction between the first input node N1 and the second input node N2.

like it in 2 As shown, the first power supply circuit 5 is a power supply circuit operated by driving the power supply IC 4, and is a switching power supply circuit formed by combining MOS transistors M2 and M3, an inductor Lo and a capacitor Co in the illustrated form. The drains and sources of the MOS transistors M2 and M3 are connected in series between the input node N1 and the ground, the coil Lo and the capacitor Co are connected in series between the common connection point of these MOS transistors M2 and M3 and the ground, and the first power supply voltage Vo6 is output from the common connection point of the coil Lo and the capacitor Co.

The power supply IC 4 includes a switching control circuit 11, a changeover switch 12, a first threshold setting section 13, a second threshold setting section 14 and an operation timing signal generation circuit 15. The switch control circuit 11 controls turning on and off of the switch M1 based on the detection state of the first power supply voltage Vo6 of the first power supply circuit 5.

A predetermined first threshold is input to the changeover switch 12 from the first threshold setting section 13 , and a predetermined second threshold is input to the changeover switch 12 from the second threshold setting section 14 . The changeover switch 12 is normally switched to the first threshold value setting section 13 side and outputs the first threshold value of the first threshold value setting section 13 to the duty signal generation circuit 15 . Here, the duty signal generating circuit 15 applies a respective pulse to the MOS transistors M2 and M3 complementary to each other and adjusts the duty ratio of the pulse to set and output the first power supply voltage Vo6 to a predetermined power supply voltage value Vo6b (e.g., 6.0 V).

When the first power supply voltage Vo6 of the first power supply circuit 5 falls below a predetermined threshold, the switching control circuit 11 turns on the switch M1, and the changeover switch 12 changes to the second threshold setting section 14 to output a second threshold to the duty signal generating circuit 15. The duty signal generation circuit 15 outputs a power supply voltage value Vo6b from the first power supply circuit 5 within a predetermined range based on the second threshold value, the details of which will be described later. The power supply voltage value Vo6b is a voltage value that is set lower than the aforementioned predetermined power supply voltage value Vo6a.

like it in 3 1, the second power supply circuit 6 is a power supply series circuit that outputs a power supply voltage of, for example, 5.0 V as the second power supply voltage Vo5 by controlling the gate of the MOS transistor M4 by the second power control circuit 21. The calculator 8 uses the second power supply voltage Vo5 as a reference voltage for the A/D conversion circuit.

The third power supply circuit 7 includes a third power control circuit 31, MOS transistors M5 and M6, a coil Lo2, and a capacitor Co2, and is a switching power supply circuit that outputs, for example, power of 1 V as a third power supply voltage Vo1. The calculator 8 uses the third power supply voltage Vo1 as its core supply voltage. In order for the computer 8 to continue its operation, it is necessary to ensure the operational guarantee range of the nuclear energy supply.

The operation of supplying power to the calculator 8 in the above configuration will be explained with reference to FIG 4 shown flow chart and drawings 5 described. Normally, the switching control circuit 11 of the power supply IC 4 turns off the switch M1 in step S1, and the power supply IC 4 controls the first power supply circuit 5 to the off state of the switch M1. Normally, the power supply IC 4 switches the changeover switch 12 to the first threshold value section 13 side to input the first threshold value of the first threshold value setting section 13 to the duty signal generation circuit 15 .

The duty signal generation circuit 15 applies a respective PWM pulse to the MOS transistors M2 and M3 complementary to each other and adjusts the duty ratio of the PWM pulse to set and output the first power supply voltage Vo6 to a predetermined power supply voltage value Vo6b (e.g. 6.0 V).

The power supply IC 4 detects the first power supply voltage Vo6 as the output voltage of the first power supply circuit 5 and determines whether the first power supply voltage Vo6 exceeds the threshold voltage Vt1 (for example, 4.6 V) in step S2. When the first power-supply voltage Vo6 exceeds the threshold voltage Vt1, the power-supply IC 4 sets the predetermined power-supply voltage value Vo6a (e.g., 6.0 V) as the target value of the first power-supply voltage Vo6 and continues the power supply in step S3 as a normal operation.

On the other hand, the second power supply circuit 6 and the third power supply circuit 7 receive the first power supply voltage Vo6 from the first power supply circuit 5 and generate the second power supply voltage Vo5 and the third power supply voltage Vo1 to supply them to the calculator 8 . Here, the second power supply circuit 6 outputs a predetermined power supply voltage value Vo5a (for example, 5.0 V) as the second power supply The third power supply circuit 7 outputs a predetermined power supply voltage value Vo1a (e.g., 1.0 V) as the third power supply voltage Vo1. On the other hand, the initialization command circuit 9 determines that neither the power supply voltage Vo5 of the second power supply circuit 6 nor the power supply voltage Vo1 of the third power supply circuit 7 is abnormal, so that it does not issue an initialization command to the computer 8. As a result, the calculator 8 operates normally.

like it in 5 1, however, the first power supply voltage Vo6 decreases as the VB voltage decreases from time t0. Thereafter, when the VB voltage falls below the predetermined first threshold voltage Vtb and the first power supply voltage Vo6 of the first power supply circuit 5 falls below the predetermined output threshold voltage Vt1a at time t1, the result of the determination in step S2 is the 4 negative, and the process proceeds to step S4.

The switching control circuit 11 turns on the switch M1 in step S4 to input the BATT voltage input to the second input node N2 to the first input node N1. The voltage of the first input node N1 is maintained as much as possible by the BATT voltage supply even when the VB voltage drops below the first threshold voltage Vtb. Also, at this time, the power supply IC 4 switches the changeover switch 12 from the first threshold setting section 13 side to the second threshold setting section 14 side and inputs the second threshold to the duty signal generation circuit 15 .

The duty signal generation circuit 15 receives the second threshold value and adjusts the duty ratio of the PWM pulse according to the second threshold value in step S5 so that the first power supply circuit 5 outputs the first power supply voltage Vo6 as a target value of the power supply voltage value Vo6b (e.g. 4.3 V) lower than the output threshold voltage Vt1a. It is desirable that the target power supply voltage value Vo6b is set to a voltage within a predetermined voltage range that is lower than the initialization threshold value Vti (e.g. 4.5V) and exceeds a predetermined lower limit voltage (e.g. 4.0V). Then it is possible to continue supplying the operation guarantee voltage to the computer 8 at the time of shutdown without returning to the normal operation voltage exceeding the initialization threshold value Vti.

The switching control circuit 11 of the power supply IC 4 keeps the switch M1 on for a predetermined time (for example, 100 µs) and then turns it off. In the example that in 5 1, the switch M1 is turned on for a predetermined time from a predetermined time t2a after the time t2.

Then, the power supply voltage value Vo6b can be maintained as the first power supply voltage Vo6 of the first power supply circuit 5 during a predetermined time from the time t2a to the time t4. The second power supply circuit 6 can generate the second power supply voltage Vo5 based on the power supply voltage value Vo6b and can maintain the predetermined power supply voltage value Vo5b as the second power supply voltage Vo5 for output. On the other hand, the third power supply circuit 7 generates the third power supply voltage Vo1 based on the power supply voltage value Vo6b and can maintain the predetermined power supply voltage value Vo1a as the output third power supply voltage Vo1. That is, the third power supply circuit 7 can set and output the power supply voltage value Vo1a as the third power supply voltage Vo1 equal to or higher than the voltage Vmin at which the operation of the computer 8 can be guaranteed at least.

On the other hand, after the initialization delay time Td has elapsed from time t2 at time t3, the initialization command circuit 9 outputs the reset signal INIT when the second power supply voltage Vo5 falls below the initialization threshold value Vti (e.g., 4.5 V). When the reset signal INIT is input, the calculator 8 saves the working memory data of the RAM in the non-volatile memory.

The computer 8 requires a predetermined preprocessing time Td2 (see 5 ) to run this procedure. However, since the power supply time of the calculator 8 extends by the third power supply voltage Vo1 of the third power supply circuit 7 to a time exceeding the predetermined time Td plus the pre-processing time Td2, the calculator 8 can perform the backup processing while ren the core voltage is specified within the operating guarantee range. As a result, the computer 8 can perform pre-processing before shutdown to save the working memory data of the RAM in the non-volatile memory.

After the calculator 8 completes the initialization process, the switching control circuit 11 turns off the switch M1 at the time t4 and thereafter stops the voltage adjustment operation of the first power supply circuit 5, the second power supply circuit 6 and the third power supply circuit 7. The calculator 8 can in step S7 the 4 shut down or switched off. As a result, the operations of the first power supply circuit 5, the second power supply circuit 6, and the third power supply circuit 7 can be stopped, processing such as saving RAM data in a non-volatile memory before shutting down the computer 8 can be performed, and the pre-processing time Td2 can be ensured.

comparative example

6 shows the operation of a comparative example. 6 shows an example of operation of a configuration using the switch M1 of the in 1 shown configuration does not have. The BATT voltage cannot be supplied from the vehicle battery 3 if the switch M1 is not provided. At this time, even if the VB voltage shows a drop from time t0 in 6 starts off, the first power supply circuit 5 continues to generate the first power supply voltage Vo6 based on the VB voltage.

Then, the initialization instruction circuit 9 outputs the reset signal INIT to the calculator 8 after the initialization delay time Td elapses after the second power supply voltage Vo5 of the second power supply circuit 6 falls below the initialization threshold value Vti. Therefore, the calculator 8 performs pre-processing for shutdown from time t3 when the reset signal INIT is input. The third power supply circuit 7 supplies the third power supply voltage Vo1 from the energy stored in the capacitor Co3. However, due to the increase in power consumption, it becomes difficult to secure the power for the calculator 8 to operate during the pre-processing time Td2. In order to secure the required electric power, it is necessary to provide a larger capacity capacitor Co3, and hence higher assembly cost and larger circuit area arise.

Summary of the present embodiment

On the other hand, the first power supply circuit 5 according to the present embodiment sets the first power supply voltage Vo6 to a power supply voltage value Vo6b lower than the output threshold voltage Vt1a and continuously outputs it during a predetermined time, so that a preprocessing time Td2 of the calculator 8 is ensured. The computer 8 can perform measures such as saving the working memory data of the RAM in the non-volatile memory during the pre-processing time Td2. As a result, it is possible to extend the power supply time of the BATT voltage for the calculator 8 during shutdown.

In particular, during the preprocessing time Td2 of the computer 8, the BATT voltage is supplied to the first energy supply circuit 5 through the BATT connection T2, so that energy generation by the first energy supply circuit 5 can be supported.

By turning on the switch M1, the power supply time by the BATT voltage can be secured, and the initialization preprocessing time Td2 for initialization can be secured. Therefore, the capacitance of the downstream capacitor Co2 constituting the third power supply circuit 7 can be reduced, and the vehicle control apparatus can be advantageously designed in terms of cost and circuit area.

In the above embodiment, the switch M1 is turned on during a predetermined period of time from the time t2a to the time t4. However, the present invention is not limited to this configuration. The switch M1 may be turned on during a predetermined time from time t2 or during a predetermined time from time t1 that the power supply voltage Vo6 falls below the predetermined output threshold voltage Vt1a.

Comparison with the technology according to JP H11-266547 A as a comparative example

A comparison between the present embodiment and the technology disclosed in FIG JP H11- 266 547 A is described. In the configuration of JP H11 - 266 547 A , which is described in the above chapter "Prior Art", it is necessary to provide two systems, each system a power supply circuit for inputting the +B voltage corresponding to the VB voltage and a power supply circuit for inputting the BATT voltage, and connecting these two systems in parallel.

On the other hand, in the present embodiment, the first power supply circuit 5 is provided by a system such that the second power supply circuit 6 and the third power supply circuit 7 generate the power supply voltages Vo5 and Vo1 based on the first power supply voltage Vo6, and only the switch M1 needs to be added. That is, there is no need to provide two systems, each of the systems generating the VB voltage or the BATT voltage, which are the base voltages.

like it in 7 is shown, when the target value of the first power supply voltage Vo6 returns to the initial power supply voltage value Vo6a after the first power supply voltage Vo6 has dropped below the initialization threshold value Vti, normal power supply voltage values Vo6a, Vo5a and Vo1a are supplied to the calculator 8 as the first power supply voltage Vo6, the second power supply voltage Vo5 and the third power supply voltage Vo1, respectively. Therefore, after time t10, the calculator 8 cannot continue the initialization state, and the calculator 8 cannot be reset normally.

In the present embodiment, since the first power supply voltage Vo6 is maintained at a predetermined voltage (e.g., 4.3 V) lower than the initialization threshold Vti, the calculator 8 can maintain the initialization state. In this way, the present embodiment differs from the technology disclosed in FIG JP H11- 266 547 A is described.

Other embodiments

The present invention is not limited to the embodiments described above. For example, the following modifications or extensions are possible.

The second power supply circuit 6 and the third power supply circuit 7 can be provided as needed. In addition, the present invention can be applied to a configuration in which another power supply circuit for supplying the power supply voltage to the calculator 8 is provided.

The control circuitry and method performed by the electronic control unit 1 described herein may be implemented by an associated computer including a processor programmed to perform one or more functions performed by a computer program and memory. Alternatively, the electronic control unit 1 and the method according to the present invention can be achieved by an associated computer containing a processor with one or more associated hardware logic circuits. Alternatively, the electronic control unit 1 and the method according to the present invention can be achieved using one or more associated computers containing a combination of the processor programmed to perform one or more functions and the memory and the processor with one or more hardware logic circuits. The computer program may also be stored on a computer-readable non-transitory tangible recording medium as computer-executable instructions.

Although the present invention has been described in terms of the embodiments thereof, it goes without saying that the present invention is not limited to the embodiments and the structures thereof. The present invention includes various modifications and variations within the equivalent range. In addition to the various combinations and configurations, other combinations and configurations including one or more elements are possible within the scope of the present invention.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• JP H11266547 A [0004, 0005, 0038, 0041]

Claims (4)

Vehicle electronic control unit for inputting a first voltage supplied from a vehicle battery via a vehicle start switch and a second voltage constantly supplied from the vehicle battery, the vehicle electronic control unit comprising: a first power supply circuit (5) configured to operate a calculator based on setting a first voltage to a first power supply voltage and outputting the first power supply voltage; a switch (M1) connected between a second input node (N2) for inputting the second voltage and a first input node (N1) for inputting the first voltage; and a switch control circuit (11) adapted to turn the switch on and off, wherein when the first voltage falls below a predetermined first threshold voltage that causes the first power supply voltage of the first power supply circuit to fall below a predetermined output threshold voltage, the switching control circuit inputs the second voltage to the first input node by turning on the switch, and the first power supply circuit sets the first power supply voltage to a power supply voltage value lower than an output threshold voltage and outputs it for maintaining operation of the calculator. Vehicle electronic control unit claim 1 wherein the first power supply circuit sets and outputs the power supply voltage value to be equal to or greater than the voltage at which the calculator can continue to operate. Vehicle electronic control unit claim 1 , wherein after the computer has completed initialization, the first power supply circuit continuously outputs the power supply voltage value for a certain period of time to ensure a pre-processing time before resetting the computer, the switch control circuit turns off the switch, stops a voltage adjustment operation of the first power supply circuit and shuts down the computer. Vehicle electronic control unit claim 1 further comprising: a second power supply circuit (6) configured to generate a second power supply voltage to be supplied to the calculator based on the first power supply voltage of the first power supply circuit, a third power supply circuit (7) configured to generate a third power supply voltage to be supplied to the calculator based on the first power supply voltage of the first power supply circuit, and an initialization command circuit (9) configured to output a reset signal to the calculator when the second power supply voltage of the second power supply circuit or the third power supply voltage of the third power supply circuit falls to an abnormal threshold voltage indicative of an abnormality.

Images