JPH0947066A - Controller for permanent magnet type synchronous motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance the torque control performance while shortening the work time by determining a pole position detection error, i.e., the phase difference between an induced voltage waveform and an output signal from a pole position sensor, and then correcting a pole position detection value based on the pole position detection error thus determined thereby eliminating the pole position detection error through operation in a control circuit. SOLUTION: A control circuit 10 is provided with a pulse processing circuit 104 receiving output signals PU, PV, PW, PA, PB from an absolute encoder 8 and an incremental encoder 9. An adder 105 subtracts a pole position error detection value ΔθAVR stored in a memory 106 from a pole position detection value θ1 outputted from the pulse processing circuit 104 thus producing a corrected pole position detection value θ. Since an operated pole position detection error is subtracted from a pole position detection value without mechanically adjusting the fixing position of a pole position sensor after it is fixed, effect of the pole position detection error on the torque error can be eliminated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a controller for a permanent magnet type synchronous motor used as an electric motor for driving a vehicle of, for example, an electric vehicle.

[0002]

2. Description of the Related Art In order to drive a permanent magnet type synchronous motor, it is necessary to know the magnetic pole position, which is the direction of the magnetic flux produced by the permanent magnet. Therefore, in many of the permanent magnet type synchronous motors, a magnetic pole position sensor is attached to the rotor shaft. For example, an absolute encoder or the like that outputs three signals U, V, and W whose phases are shifted by 120 degrees is used for the magnetic pole position sensor. In this absolute encoder, the output signal is a predetermined position (phase) relative to the magnetic pole position. ) Is attached.

In the text, the above-mentioned predetermined position is shown in FIG.
As shown in, the zero crossing point of the rising edge of the U-phase induced voltage e _{U and} the rising edge of the U-phase signal P _U of the absolute encoder coincide with each other. Further, hereinafter, the magnetic pole position detection error means a phase difference between the U-phase induced voltage e _U and the U-phase signal P _U of the absolute encoder. In addition,
In FIG. 5, e _V and e _W are the V-phase induced voltage and the W-phase induced voltage, respectively, and P _V and P _W are the V-phase signal and the W-phase signal of the absolute encoder, respectively.

It is generally difficult to mount the absolute encoder on the rotor shaft so that the magnetic pole position detection error is zero because of the influence of machining accuracy of the sensor mounting portion and variations in the magnetization of the permanent magnets. So, after installing the absolute encoder within a certain accuracy,
The electric motor is rotated by the load machine so that the zero-cross point of the rising of the U-phase induced voltage e _{U and} the rising of the U-phase output pulse P _U of the absolute encoder match.
That is, it is necessary to mechanically adjust the mounting position of the absolute encoder so that the magnetic pole position detection error becomes zero.

The work of adjusting the mounting position of the absolute encoder is individually performed for each of the plurality of permanent magnet type synchronous motors due to variations in the magnetization of the permanent magnets as described above.

[0006]

The magnetic pole position detection error is
Since it affects the magnitude of output torque, it becomes a big problem when trying to perform highly accurate torque control. After installing the absolute encoder which is the magnetic pole position sensor,
With the method of adjusting the mounting position to reduce the magnetic pole position detection error, it is difficult to completely eliminate the magnetic pole position detection error, and much time and labor are required for accurate adjustment. Furthermore, in order to make this adjustment, a load machine that rotates a permanent magnet type synchronous motor is required,
The sensor part must be processed so that the mounting position can be finely adjusted, or a dedicated jig must be prepared.

Therefore, in the method of adjusting the mounting position of the absolute encoder, the torque control performance is deteriorated due to the fact that the magnetic pole position detection error cannot be reduced, the working time is lengthened, the cost for procurement of equipment and processing for adjustment, etc. are increased. Cause problems. Furthermore, since this adjustment work must be performed for each electric motor, the above problem becomes serious in mass production.

The present invention has been made to solve the above problems, and its object is to perform calculation in the control circuit of a permanent magnet type synchronous motor regardless of the method of adjusting the mounting position of the magnetic pole position sensor. Therefore, it is an object of the present invention to provide a control device for a permanent magnet type synchronous motor, which eliminates the magnetic pole position detection error and solves the problems of torque control performance, working time, and cost increase.

[0009]

In order to achieve the above-mentioned object, the invention described in claim 1 is an inverter for driving a permanent magnet type synchronous motor in which a magnetic pole position sensor is attached to a rotor shaft, and the inverter. A controller for a permanent magnet synchronous motor, comprising: an opening / closing means provided between the motor and a motor; and a control circuit for controlling an inverter based on a detected value of a magnetic pole position of the motor based on an output signal of the magnetic pole position sensor. A means for detecting the induced voltage waveform of the electric motor by opening the opening / closing means after closing, a means for obtaining a magnetic pole position detection error which is a phase difference between the induced voltage waveform and the output signal of the magnetic pole position sensor, and the obtained magnetic pole. And a means for correcting the magnetic pole position detection value based on the position detection error.

In the present invention, for example, a contactor is provided as the opening / closing means, and the induced voltage appearing at the terminal of the electric motor is detected at a predetermined rotation speed such that the induced voltage of the electric motor can be sufficiently detected with the contactor opened. . This induced voltage is used to determine the magnetic pole position detection error, and the magnetic pole position is corrected by subtracting the magnetic pole position detection error from the magnetic pole position detection value obtained based on the output signal of the magnetic pole position sensor in the motor control circuit. To do.

Here, assuming that the magnetic pole position detection error is Δθ, the relationship between the torque command value τ ^* of the electric motor and the output torque τ is roughly expressed by the following equation. τ = τ ^* × cos (Δθ) That is, the influence of the magnetic pole position detection error Δθ is cos.
It appears as an error in the output torque τ as a function.

According to the first aspect of the present invention, when there is a magnetic pole position detection error due to an error in the mounting position of the magnetic pole position sensor, the magnetic pole position including the error in the mounting position is not mechanically adjusted but the sensor mounting position is mechanically adjusted. By subtracting the magnetic pole position detection error from the detected value, the influence of the magnetic pole position detection error on the torque can be eliminated. Further, by using the induced voltage waveform that appears at the terminals of the electric motor when the opening / closing means such as the contactor is opened, the phase difference between this induced voltage and the output signal of the magnetic pole position sensor can be obtained to accurately obtain the magnetic pole position detection error. You can Further, by opening the opening / closing means, it is possible to obtain the magnetic pole position detection error in a state where the permanent magnet type synchronous motor having the magnetic pole position sensor at the shaft end is incorporated in the system for actually driving the permanent magnet type synchronous motor.

According to a second aspect of the present invention, in the first aspect of the invention, when the permanent magnet type synchronous electric motor is actually driven by the inverter with the opening / closing means closed, the electric motor reaches a certain rotational speed. The magnetic pole position detection error is obtained by opening the opening / closing means, and the specific method of obtaining the magnetic pole position detection error is as described in claims 3 and 4. According to the present invention, in a system in which a permanent magnet type synchronous motor having a magnetic pole position sensor at the shaft end is incorporated into a product level system for actually driving the permanent magnet type synchronous motor, a load machine is not used, and a system is provided. It is possible to obtain the magnetic pole position detection error by means of item 4 or the like.

According to a third aspect of the present invention, in the second aspect of the present invention, it is provided with an incremental encoder which is attached to the rotor shaft of the electric motor and outputs two pulses having different phases, and the pulse counting means. The pulse in the phase difference between the induced voltage waveform of the electric motor and the output signal of the magnetic pole position sensor is counted by the counting means to obtain a magnetic pole position detection error.

An incremental encoder that outputs two pulses with different phases has a higher angular resolution than an absolute encoder. Therefore, for example, the phase difference between the rising of the U-phase signal and the zero crossing of the rising of the U-phase induced voltage of the absolute encoder which is the magnetic pole position sensor, that is, the magnetic pole position detection error is obtained by counting the above two pulses. According to the present invention, the magnetic pole position detection error can be obtained with the resolution of the two output pulses of the incremental encoder.

According to a fourth aspect of the present invention, in the second aspect of the present invention, the rotational speed detecting means and the time measuring means of the electric motor are provided, and the phase difference between the induced voltage waveform of the electric motor and the output signal of the magnetic pole position sensor is calculated. The corresponding time is measured by the time measuring means, and this time is multiplied by the rotation speed of the electric motor measured by the rotation speed detecting means to obtain the magnetic pole position detection error.

In the present invention, the time of the phase difference between the U-phase signal and the U-phase induced voltage of the absolute encoder which is the magnetic pole position sensor is measured. Since the magnetic pole position of the electric motor is an angle, the magnetic pole position detection error is obtained by multiplying it by the rotation speed. In this method, the magnetic pole position detection error can be obtained with the resolution used in the control circuit by increasing the time resolution.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. First, an embodiment of the invention according to claims 1 to 3 will be described. FIG. 1 shows the overall configuration of this embodiment. In the figure, 1 is a torque command device, 2 is a DC power supply, 3 is a voltage detector, 4 is an inverter, 5 is a current detector, and 6 is a switching device. A motor contactor as a means, 7 is a permanent magnet type synchronous motor, 8 is a signal P _{U of} each phase of U, V and W,
An absolute encoder as a magnetic pole position sensor that outputs P _V and P _W , 9 is two signals P _A and P _B with different phases
Incremental encoder for outputting 10 is a control circuit, and 11 is a magnetic pole position error detection circuit. Here, the configurations and operations of the control circuit 10 and the magnetic pole position error detection circuit 11 form the main part of the present invention.

In the control circuit 10, 104 is an absolute encoder 8 and an incremental encoder 9.
Pulse processing circuit to which the output signals P _U , P _V , P _W , P _A , and P _B are added, and 105 is a magnetic pole position error stored in the memory 106 from the magnetic pole position detection value θ ₁ output from the pulse processing circuit 104 An adder that subtracts the detection value Δθ _AVR and outputs a magnetic pole position detection value correction value θ, 101 is a torque command value τ ^* by the torque command device 1, a DC voltage detection value V _DC by the voltage detector 3, and the magnetic pole. The position detection value correction value θ, the rotational angular velocity ω output from the pulse processing circuit 104, and the AC current detection value i from the current detector 5 are input, and the gate drive signal based on a predetermined switching pattern is input to the inverter 4. Is a torque controller, 102 is a control mode switch for switching between the normal operation mode and the magnetic pole position error detection mode by selecting logic "1" or "0", and 103 is a motor contact. Motor contactor control circuit that controls the opening and closing of the 6, a comparator for comparing the rotational angular velocity omega reference velocity omega 'and 1031, 1032 output signal and the control mode selector switch 1 of the comparator 1031
An AND circuit that outputs an opening / closing control signal for the motor contactor 6 by ANDing with the output signal of 02.

In the magnetic pole position error detection circuit 11, 111 is a phase voltage detection circuit for detecting the phase voltage of each of the three phases from the AC side of the synchronous motor 7, and 112 is the phase voltage detection value e _U of the U phase, for example. comparator for converting a square wave E _U, 1
14 latch circuit latches the magnetic pole position detection value theta ₁ at the rising edge of the square wave E _U, and outputs it as a magnetic pole position error detecting value [Delta] [theta] _n, 115 is the average value of the magnetic pole position error detection value [Delta] [theta] _n The average value calculation circuit calculates and outputs a new magnetic pole position error detection value Δθ _AVR . Then, the detected magnetic pole position error value Δθ _AVR is stored in the memory 106.

Next, the operation of this embodiment will be described. This system has two operation modes, and it is possible to switch between the normal operation mode and the magnetic pole position error detection mode by the control mode changeover switch 102 in the control circuit 10. However, in the present system, when the absolute encoder 8 is attached to the shaft end of the rotor of the permanent magnet type synchronous motor 7, after the control power is turned on, the magnetic pole position error detection mode is always operated first to eliminate the magnetic pole position detection error. After determining, the sequence is to operate in the normal operation mode. Then, in the normal operation mode, the operation is performed using the magnetic pole position detection value correction value θ after compensation by the magnetic pole position error detection value Δθ _AVR obtained in the magnetic pole position error detection mode.

First, the normal operation mode will be described in detail. In the normal operation mode, the control mode switch 102 is set to the "0" side. Torque command device 1
The torque command value τ ^* is input to the torque controller 101 in the control circuit 10.

In the torque controller 101, the DC voltage detected value V _DC by the voltage detector 3 and the output signals P _{U of} the absolute encoder 8 and the incremental encoder 9 are
Magnetic pole position detection value obtained by subtracting the magnetic pole position error detection value Δθ _AVR in the memory 106 from the magnetic pole position detection value θ ₁ calculated by the pulse processing circuit 104 based on P _V , P _W , P _A , P _B Using the correction value θ, the rotational angular velocity ω obtained by counting the output signals P _A and P _B of the incremental encoder 9 per unit time, and the current detection value i by the current detector 5,
Generate a switching pattern such that the permanent magnet type synchronous motor 7 outputs the torque according to the torque command value τ ^* ,
The gate drive signal of the inverter 4 is output.

In the inverter 4, the DC voltage V _DC supplied from the DC power supply 2 is switched in accordance with the gate drive signal to generate a predetermined voltage and current in the permanent magnet type synchronous motor 7.
To supply.

Next, the operation of the magnetic pole position error detection mode will be described. In this magnetic pole position error detection mode, the control mode changeover switch 102 is set to the "1" side. In this mode, the torque command device 1 outputs the torque command value τ
^{The operation} of instructing ^* to drive the permanent magnet type synchronous motor 7 is the same as in the normal operation mode.

However, when operating in the magnetic pole position error detection mode, the magnetic pole position error detection value Δθ _AVR stored in the memory 106 is zero, and moreover, the mounting position and the magnetic pole position of the absolute encoder 8 which is the magnetic pole position sensor. The error between and is such that the permanent magnet synchronous motor 7 can be rotated with a torque accuracy within a certain range.

When the permanent magnet type synchronous motor 7 is driven in this magnetic pole position error detection mode, the rotational angular velocity ω is the reference angular velocity ω ′ at which the zero cross of the motor induced voltage can be detected.
When the above is reached, the motor contactor 6 is turned off via the comparator 1031 and the AND circuit 1032. Specifically, the logic of the two inputs of the AND circuit 1032 becomes "1", thereby opening the motor contactor 6. When the motor contactor 6 is turned off, an induced voltage appears at the terminals of the permanent magnet type synchronous motor 7, and this induced voltage is input to the phase voltage detection circuit 111 of the magnetic pole position error detection circuit 11.

The operation of the magnetic pole position error detection circuit 11 will be described below with reference to the signal waveform of FIG. The induced voltage taken into the magnetic pole position error detection circuit 11 is, for example, a U-phase voltage (U-phase induced voltage) by the phase voltage detection circuit 111.
It is converted into e _U and further converted into a square wave E _U by the comparator 112. At a rising edge of the square wave E _U, latches the magnetic pole position detection value theta ₁ which is output from the pulse processing circuit 104 by the latch circuit 114.

Latching the magnetic pole position detection value θ ₁ is equivalent to counting the output signals P _A and P _B of the incremental encoder 9, and the latched data becomes the magnetic pole position error detection value Δθ _n . This operation is performed n times in n cycles, the average value of the magnetic pole position error detection values Δθ _n at each time is calculated by the average value calculation circuit 115 to obtain a new magnetic pole position error detection value Δθ _AVR , and this value is stored in the memory 106. Memorized in.

Magnetic pole position error detection value Δθ in the memory 106
By subtracting _AVR from the magnetic pole position detection value θ ₁ by the adder 105 to obtain the magnetic pole position detection value correction value θ, the zero crossing of the rising of the U phase induced voltage e _U and the U phase signal P of the absolute encoder 8 are equivalently obtained. The rising edge of _U can be matched.

Next, an embodiment of the invention according to claims 1, 2 and 4 will be described. FIG. 3 shows the overall configuration of this embodiment. What is different from FIG. 1 is the magnetic pole position error detection circuit 11A.
Since this is the only configuration, this section will be mainly described. The same components as those in FIG. 1 are denoted by the same reference numerals.

In the magnetic pole position error detection circuit 11A shown in FIG. 3, the square wave E _U output from the comparator 112 and the U-phase signal P _U output from the absolute encoder 8 are input to the counter control circuit 116, which outputs the control signal. Are input to the start input terminal, the stop input terminal, and the reset input terminal of the up / down counter 117. Reference numeral 119 is a clock generation circuit.

The output signal C _CLK of the counter 117 is input to the latch circuit 114, the signal C _CLK at the rising edge of the control signal applied to the stop input terminal of the counter 117
Are configured to be latched. Here, the counter control circuit 116, the up / down counter 117,
The clock generation circuit 119 and the latch circuit 114 constitute time measuring means.

The output signal of the latch circuit 114 is the multiplier 1
At 18, the rotational angular velocity ω which is the output of the pulse processing circuit 104 as the rotational velocity detecting means is multiplied, and the result is used as the magnetic pole position error detection value Δθ _n to calculate the average value arithmetic circuit 11
5 is input. The subsequent structure is the same as that shown in FIG.
_The magnetic pole position error detection value Δθ _AVR, which is the average value of _n , is stored in the memory 106 of the control circuit 10.

The operation of this embodiment will be described below. Here, except for the part described with reference to FIG. 1, the operation in the magnetic pole position error detection circuit 11A that is peculiar to the present embodiment will be described with reference to FIG.
This will be described with reference to the signal waveforms of.

First, similarly to the above, the induced voltage between the lines is converted into the U-phase voltage e _U by the phase voltage detection circuit 111 and further converted into the square wave E _U. The square wave E _U and the U-phase signal P _U of the absolute encoder 8 are the counter control circuit 1
16 is input. At this time, the counter control circuit 116
As shown in FIG. 4, the clock from the clock generation circuit 119 from the rising edge of the E _U or P _U to the other of the rising edge, the counter 117 outputs a control signal to count.

That is, as shown in the upper part of FIG. 4, when the phase of E _U lags behind P _U , the counter 117 outputs P _U.
It starts counting from the rise timing, E _U
Counting ends at the rising edge of. Further, when the phase of the E _U as shown in the lower part of FIG. 4 is ahead of the P _U, the counter 117 starts counting from the rise timing of E _U, the control section 10 ends the counting at the rising edge of the P _U , The polarity of this count output signal C _CLK is inverted.

[0038] The count output signal C _CLK is input to the latch circuit 114, E _U, phase delay advances the signal by E _U of P _U, is latched on the rising edge of P _U. The latched data, that is, the data corresponding to the time between the rising zero cross of the U-phase induced voltage e _U and the rising edge of the U-phase signal P _U of the absolute encoder 9 is multiplied by the rotation angular velocity ω by the multiplier 118, and the magnetic pole position The error detection value Δθ _n is obtained. This operation is repeated for n cycles
The average value calculation circuit 115 calculates the average value of the magnetic pole position error detection values Δθ _n for each time to obtain a new magnetic pole position error detection value Δθ _AVR , and the new value is stored in the memory 106.

Therefore, similarly to the above, by subtracting the magnetic pole position error detection value Δθ _AVR in the memory 106 from the magnetic pole position detection value θ ₁ to obtain the magnetic pole position detection value correction value θ, the U-phase induced voltage e is equivalently obtained. The zero crossing of the rising edge of _{U and} the rising edge of the U-phase signal P _U of the absolute encoder 8 can be matched.

[0040]

As described above, according to the present invention, the magnetic pole position detection error obtained by calculation can be subtracted from the magnetic pole position detection value without mechanically adjusting the mounting position after the magnetic pole position sensor is mounted. Thus, the influence of the magnetic pole position detection error on the torque error can be eliminated. At the same time, it saves a great deal of time and labor required for conventional mounting position adjustment work, eliminates the need for processing on the sensor section and dedicated jigs, and increases the cost of equipment procurement and processing for adjustment. It is possible to realize a control device excellent in mass productivity without any problem.

According to the first aspect of the present invention, the induced voltage required for obtaining the magnetic pole position detection error can be accurately detected by opening the opening / closing means provided between the inverter and the electric motor. it can. As a result,
It is possible to accurately detect the magnetic pole position detection error.
Further, in a state in which the permanent magnet type synchronous motor having a magnetic pole position sensor at the shaft end of the rotor is incorporated in a system which actually drives the permanent magnet type synchronous motor by opening the opening / closing means, It is possible to obtain the magnetic pole position detection error by means of item 4 or the like.

According to the second aspect of the present invention, the load machine is mounted in a state where the permanent magnet type synchronous motor having the magnetic pole position sensor at the shaft end of the rotor is incorporated in the system for actually driving the permanent magnet type synchronous motor. Accurate detection of the magnetic pole position detection error is possible without using it, and means for obtaining the magnetic pole position detection error is specifically provided by the inventions of claims 3 and 4.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram showing an embodiment of the invention described in claims 1 to 3.

FIG. 2 is a signal waveform diagram showing an operation of the magnetic pole position error detection circuit in FIG.

FIG. 3 is an overall configuration diagram showing an embodiment of the invention described in claims 1, 2 and 4.

FIG. 4 is a signal waveform diagram showing an operation of the magnetic pole position error detection circuit in FIG.

FIG. 5 is a waveform diagram showing each phase induced voltage and each phase signal of the absolute encoder.

[Explanation of symbols]

 1 Torque Command Device 2 DC Power Supply 3 Voltage Detector 4 Inverter 5 Current Detector 6 Motor Contactor 7 Permanent Magnet Type Synchronous Motor 8 Absolute Encoder 9 Incremental Encoder 10 Control Circuit 101 Torque Controller 102 Control Mode Change Switch 103 Motor Contactor Control Circuit 1031 Comparator 1032 AND circuit 104 Pulse processing circuit 105 Adder 106 Memory 11, 11A Magnetic pole position error detection circuit 111 Phase voltage detection circuit 112 Comparator 114 Latch circuit 115 Average value calculation circuit 116 Counter control circuit 117 Up-down counter 118 Multiplier 119 Clock generation circuit

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Yoshinobu Sato 1-1 Tanabe Nitta, Kawasaki-ku, Kawasaki-shi, Kanagawa Fuji Electric Co., Ltd. No. 1 in Fuji Electric Co., Ltd. (72) Inventor Toshio Kikuchi 2 Takaracho, Kanagawa-ku, Yokohama, Kanagawa Nissan Motor Co., Ltd. (72) Shinichiro Kitada 2 Takaracho, Kanagawa-ku, Yokohama, Kanagawa Nissan Motor Co., Ltd. ( 72) Inventor Go Aso, Nissan Motor Co., Ltd. 2 Takaracho, Kanagawa-ku, Yokohama-shi, Kanagawa

Claims (4)

[Claims] 1. An inverter for driving a permanent magnet type synchronous electric motor having a magnetic pole position sensor attached to a rotor shaft, and an opening / closing means provided between the inverter and the electric motor.
A controller for a permanent magnet synchronous motor having a control circuit for controlling an inverter based on a detected value of a magnetic pole position of an electric motor based on an output signal of the magnetic pole position sensor, wherein the opening / closing means is opened after turning on a control power source to induce the electric motor. Means for detecting a voltage waveform, means for obtaining a magnetic pole position detection error which is a phase difference between the induced voltage waveform and the output signal of the magnetic pole position sensor, and means for correcting the magnetic pole position detection value by the obtained magnetic pole position detection error. And a control device for a permanent magnet type synchronous motor. 2. The controller for a permanent magnet type synchronous motor according to claim 1, wherein the inverter drives the permanent magnet type synchronous motor with the opening / closing means closed, and when the electric motor reaches a certain rotation speed, A controller for a permanent magnet type synchronous motor, wherein the opening / closing means is opened to obtain a magnetic pole position detection error. 3. The controller for a permanent magnet synchronous motor according to claim 2, further comprising: an incremental encoder that is attached to a rotor shaft of the electric motor and outputs two pulses having different phases; and a counting unit that counts the pulses. A controller for a permanent magnet type synchronous motor, characterized in that the pulse in the phase difference between the induced voltage waveform of the electric motor and the output signal of the magnetic pole position sensor is counted by the counting means to obtain a magnetic pole position detection error. . 4. The permanent magnet synchronous motor control device according to claim 2, further comprising: a motor rotation speed detection means and a time measurement means, wherein the position of the induced voltage waveform of the motor and the output signal of the magnetic pole position sensor is measured. The time corresponding to the phase difference is measured by the time measuring means, and this time is multiplied by the rotation speed of the electric motor measured by the rotation speed detection means to obtain a magnetic pole position detection error. Electric motor controller.