JP2012020008A - Wasted time compensation device and x-ray ct apparatus using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an X-ray CT apparatus able to compensate for the wasted time of a control target and for variation in wasted time.SOLUTION: A control section 8 feed-back-controls an inverter 2 by using the information of an X-ray tube transmitted to an immovable section 9 from a rotary section 10 by use of transmitting sections 20 and 21. A Smith estimating unit 80 includes a control target model circuit 81 and a wasted-time model circuit 84. A delay-time calculating section 85 calculates the wasted time caused by the transmission of the information of a radiating section by the transmitting sections 20 and 21, and compensates for the wasted time of the wasted-time model circuit. Thus, even in the case where the transmitting section carries out digital transmission with an error correction function, control using a Smith method can be exerted by compensating for delay time resulting from error correction made by the error correction function.

Description

  The present invention relates to a function for compensating a dead time of signal transmission and fluctuation thereof in an X-ray CT apparatus that controls a control target mounted on a rotating unit by a control circuit disposed in a stationary unit.

  In the X-ray CT apparatus, an X-ray tube and an X-ray detector are mounted on a rotating disk, and X-ray irradiation and detection are performed while rotating around the subject. For this reason, in order to supply power from the inverter circuit on the stationary side to the X-ray tube on the rotating disk and to pass the detection signal of the X-ray detector from the rotating disk to the stationary signal processing device, Electric power and signal transmission means are arranged at the contact portion between the two portions. For example, a transmission means combining a slip ring and a brush is widely known.

  In Patent Document 1, in order to solve the problem that wear occurs in the contact portion between the slip ring and the brush, coils are arranged on the opposing surfaces of the rotating disk and the stationary portion, and power is supplied in a non-contact manner by electromagnetic induction. Techniques to do this are disclosed.

  In paragraph 0019 of Patent Document 1, in addition to the slip ring and non-contact electromagnetic induction, the detection signal of the X-ray detector on the turntable is transmitted to the stationary part by a communication system using light or radio waves. Is described.

  Further, the control circuit of the inverter circuit of the stationary part is controlled so as to obtain a predetermined X-ray output by feeding back the tube voltage of the X-ray tube on the rotating disk. For this reason, the tube voltage signal is transmitted to the stationary part by a slip ring, non-contact electromagnetic induction, a communication system using light or radio waves.

  On the other hand, in a plant such as a thermal power plant, PID control is generally used when controlling the flow rate of fuel supplied to a boiler. The Smith method is used because feedback control becomes difficult when there is a large delay (dead time) until a response is detected from the control target after changing the control amount to the control target. For example, Patent Document 2 uses a Smith predictor for controlling the steam temperature of a boiler. The technique of Patent Document 2 calculates the dead time using an autoregressive model in order to prevent the steam temperature from being emitted when there is a fluctuation in the dead time. Further, Patent Document 3 obtains a change in the gain ratio from the output of the control target model means in order to sufficiently exert the function of the Smith method even when the characteristics and gain of the control target change in plant control, and control is performed. A technique for correcting the gain of a signal is disclosed.

Here, a general feedback control system and the Smith method will be briefly described. A normal feedback control system is shown in FIG. In FIG. 19, C (s) is a transfer function of the controller 101, G (s) is a transfer function of the controlled object 102, e- ^sL is a transfer function of a ^dead time element, R (s) is a control command, U (s) Indicates an operation amount, D (s) indicates a disturbance, and Y (s) indicates an output. In this feedback control system, when the control object 102 is only the first-order delay and there is almost no dead time L (L≈0), it can be easily controlled by PI control. However, when the dead time of the control object 102 is large, the control is greatly affected and the control becomes difficult. The transfer function of the control system in FIG. 19 at that time is expressed as shown in (Equation 1) below.

... (Formula 1)
However, no disturbance is considered (D (s) = 0). From the above equation 1, the characteristic equation of this control system is expressed as the following equation 2.

... (Formula 2)

  Since this characteristic equation includes the dead time L, when L is a size that cannot be ignored, the control performance is degraded, and the controller 101 is difficult to design.

Therefore, in order to compensate for this dead time, the Smith method is used in the conventional plant control as disclosed in Patent Documents 2 and 3. A basic configuration diagram of a control system using the Smith method is shown in FIG. In FIG. 20, the control target model 103 has a transfer function P (s) substantially equal to the transfer function G (s) of the control target 102, and the ^dead time model 104 has a transfer function e ^−sL equal to the ^dead time element. . The controlled object model 103 and the dead time model 104 are collectively referred to as a Smith predictor 105.

As shown in FIG. 20, the control system using the Smith method ^{feeds back} the transfer function P (s) of the control target model 103 to the control target 102 (transfer function G (s) e ^−sL ) having a ^{dead time.} In addition, the ^difference between the transfer function e ^{−sL of the dead} time model 104 and the transfer function G (s) e ^−sL of the control target 102 is fed back. That is, the Smith method has a control target model 103 and a dead time model 104, and performs control while always predicting a phenomenon that appears after the dead time. That is, the manipulated variable U (s) is calculated from the controlled variable, the set value R (s), and the transfer function C (s) of the controller 101, and the change of the controlled variable with respect to the manipulated variable U (s) is changed using the Smith predictor. Further, an operation amount U (s) is calculated in the controller C (s) based on the amount of change. Therefore, the transfer function from the control command value R (s) to the output Y (s) of the feedback control system provided with the Smith predictor 105 of FIG.

... (Formula 3)

If there is no error between the transfer function of the control target model 103 and the transfer function of the control target 102, that is, if P (s) = G (s), the characteristic equation is as shown in (Expression 4).
(Formula 4)
The characteristic equation of (Equation 4) is stable because the dead time L does not remain. By using the Smith predictor in this way, the influence of dead time can be eliminated from the system, and the output Y (s) can accurately follow the control command R (s). Moreover, the same controller 101 as when there is no dead time can be used.

  The Smith method eliminates wasted time from the control loop, which eliminates the wasted time in the control target, and eliminates the wasted time from the characteristic equation of the feedback control system. On the other hand, it is known that it has a feature such that it is left as it is complicated because the dead time remains as it is.

Japanese Patent No. 4008010 JP-A-62-248902 JP-A-5-35306

  In the X-ray CT apparatus, tube voltage information of the X-ray tube is fed back by a communication system such as an optical fiber, thereby controlling the power supplied to the X-ray tube by controlling the frequency and output voltage of the inverter. Since the X-ray tube is mounted on the rotating disk, when the tube voltage information is fed back to the stationary inverter circuit, transmission from the rotating disk to the stationary side is required. For transmission, slip ring, optical transmission, electrostatic transmission, radio wave, etc. are used. However, since transmission involves transmission from the rotating disk to the stationary side during transmission, a time delay (dead time) of 1 ms to several ms occurs. . In particular, when digital transmission is performed, information can be transmitted with high accuracy by error detection processing of transmitted data, error correction processing when an error is found, and the like. Time) and transmission delay (variation of dead time) occurs.

  Also, preparing an independent transmission path for transmission of tube voltage information leads to an increase in the size and cost of the apparatus. For this reason, it is conceivable to transmit the tube voltage signal using the transmission path of the X-ray detection data of the X-ray detector. In this case, since it is necessary to estimate the transmission timing of the X-ray detection data and transmit the tube voltage signal in the meantime, the variation in the waste time and the waste time becomes large.

  It is conceivable to apply the techniques described in Patent Documents 2 and 3 that use the Smith method to control a plant with a large dead time to an X-ray CT apparatus to control an inverter circuit using tube voltage information with a large dead time. . However, as described above, the Smith predictor requires a controlled object model having a transfer function equal to the controlled object and a dead time model having a transfer function equal to the dead time. An apparatus that generates a high voltage, such as an X-ray CT apparatus, includes a diode rectifier circuit that is a non-linear element in the controlled object, so that the controlled object is expressed by a transfer function or state equation required by the Smith predictor. It is difficult to create a model. In addition, since the variation in the dead time is unknown, it is difficult to create a dead time model.

  Patent Document 2 discloses a configuration for calculating the waste time of the steam temperature signal of the boiler when the fuel flow control valve to the boiler is controlled by using an autoregressive model. It is not possible to detect dead time and variations in dead time due to error detection, error correction processing, and the like during transmission of tube voltage digital data.

  The objective of this invention is providing the X-ray CT apparatus which can compensate the fluctuation | variation of the waste time of a control object, and a waste time.

  In order to achieve the above object, according to the present invention, the following X-ray CT apparatus is provided. That is, the X-ray CT apparatus includes an X-ray irradiation unit and an X-ray detection unit, a rotating unit that rotates around the subject, a power supply unit that supplies power to the X-ray irradiation unit, and a stationary unit that includes a control unit. And a transmission unit that transmits a signal from the rotating unit to the stationary unit. The control unit performs feedback control of the power supply unit using the information of the X-ray irradiation unit transmitted from the rotating unit to the stationary unit by the transmission unit. The control unit calculates a delay time caused by a Smith predictor including a control target model circuit and a dead time model circuit, and transmission of information of the X-ray irradiation unit by a transmission unit, and compensates for a dead time of the dead time model circuit A time calculation unit.

  For example, when the transmission unit is configured to perform digital transmission having an error correction function, the delay time includes a delay time caused by error correction by the error correction function.

  For example, the rotation unit is configured to include a rotation-side control unit that detects information of the X-ray irradiation unit and superimposes information indicating the time before transmission by the transmission unit and transmits the information to the transmission unit. In this case, the delay time calculation unit can calculate the delay time by obtaining the difference between the time superimposed on the information transmitted by the transmission unit and the time after transmission.

  In addition, for example, the rotation unit is configured to include a rotation-side control unit that detects the information of the X-ray irradiation unit and superimposes information indicating a number at a predetermined timing and transmits the information to the transmission unit. In this case, the delay time calculation unit can calculate the delay time from the number superimposed on the information transmitted by the transmission unit.

  Further, for example, the delay time calculation unit can receive the number of error corrections from the transmission unit and calculate the delay time using the number of error corrections and a predetermined time required for error correction.

  The control target model circuit can be configured by, for example, an operational amplifier circuit or a programmable integrated circuit equivalent to the control target.

  According to another aspect of the present invention, a control device having a dead time compensation function for performing feedback control of a control target having a dead time is provided. The control device includes a Smith predictor including a control target model circuit and a dead time model circuit, a delay time calculation unit that calculates a delay time that occurs in signal transmission from the control target, and compensates for the dead time of the dead time model circuit; Is provided.

  According to the present invention, even when a delay time occurs in the signal transmission from the rotating part to the stationary part and the delay time fluctuates, the delay time is calculated and the dead time of the dead time model circuit is calculated. Can be compensated. Therefore, even an apparatus that requires signal transmission between the rotating part and the stationary part, such as an X-ray CT apparatus, can perform highly accurate control.

1 is a block diagram showing a schematic configuration of a contactless power feeding type X-ray CT apparatus of an embodiment. The block diagram which shows the control system of the tube voltage of the X-ray CT apparatus of FIG. The flowchart which shows the calculation processing procedure of the dead time by the control system of FIG. The circuit diagram which shows the equivalent circuit of the tube voltage control circuit from the output of the inverter 2 of embodiment to the X-ray tube 7. FIG. The circuit diagram which shows the integration circuit using an operational amplifier. The circuit diagram which shows the differentiation circuit using an operational amplifier. The circuit diagram which shows the equivalent circuit which divided the equivalent circuit of FIG. 4 into three. The circuit diagram which took out the 1st equivalent circuit of the equivalent circuit divided | segmented in FIG. FIG. 8 is a model circuit diagram illustrating the first equivalent circuit of FIG. 7 by an operational amplifier circuit. The circuit diagram which extracted the 2nd equivalent circuit of the equivalent circuit divided | segmented in FIG. FIG. 10 is a model circuit diagram illustrating the second equivalent circuit of FIG. 9 as an operational amplifier circuit. The circuit diagram which extracted the 3rd equivalent circuit of the equivalent circuit divided | segmented in FIG. The model circuit diagram represented with the operational amplifier circuit of the 3rd equivalent circuit of FIG. FIG. 13 is an operational amplifier circuit diagram for compensating for a diode forward voltage drop of a diode bridge in the circuit of FIG. 12. The graph which shows the simulation result of the time response at the time of carrying out PI control of the ideal X-ray tube voltage control system with no dead time of a comparative example. The graph which shows the simulation result of the time response at the time of carrying out PI control of the X-ray tube voltage control system with the dead time of 1 ms of a comparative example. The graph which shows the simulation result of the time response at the time of applying the Smith predictor 80 to a fixed X-ray tube voltage control system with dead time 1ms. The graph which shows the simulation result of the time response at the time of applying the Smith predictor 80 to the X-ray tube voltage control system in which dead time fluctuates. The graph which shows the simulation result of the time response at the time of applying the tube voltage control circuit 8 provided with the Smith predictor 80 of this embodiment and the time delay calculating circuit 85 to the X-ray tube voltage control system in which dead time fluctuates. The block diagram which shows a general feedback control system. The block diagram which shows the control system of a general Smith method.

  Hereinafter, an X-ray CT apparatus according to an embodiment of the present invention will be described.

(First embodiment)
FIG. 1 shows an outline of the non-contact power feeding type X-ray CT apparatus of the first embodiment. As shown in FIG. 1, this X-ray CT apparatus includes a power source 1, an inverter 2, a winding transformer 3 by non-contact power feeding, a main transformer 4, a rectifier 5, a smoothing capacitor 6, and an X-ray tube. 7, a tube voltage control circuit 8, an X-ray detector 12, a signal processing unit 22, an anode rotation drive circuit 31, and a filament heating circuit 32.

  The X-ray tube 7, the main transformer 4, the rectifier 5, the smoothing capacitor 6, and the X-ray detector 12 are mounted on a rotating disk (not shown) that rotates around the subject and constitutes a rotating unit 10. Both the power source 1 and the inverter 2 are configured as a stationary part 9.

  At the position where the stationary frame on the stationary part 9 side and the rotating disk of the rotating part 10 face each other, the first winding 3a and the second winding 3b are arranged so that the magnetic fluxes are linked to each other. The winding transformer 3 to perform is comprised.

  In addition, a rotation side space transmission module 21 is mounted on the turntable of the rotation unit 10, and a stationary side space transmission module 20 is disposed on the fixed unit 9. These are communication systems that transmit information from the rotating unit 10 to the fixed unit 9 and use optical communication, electrostatic transmission, or communication systems using radio waves.

  The power source 1 of the stationary part 9 generates a DC voltage. The inverter 2 includes an inverter circuit and an inverter drive circuit, and converts the DC voltage output from the power source 1 into AC. About the structure of an inverter circuit and an inverter drive circuit, since it is a well-known structure described in Unexamined-Japanese-Patent No. 2005-94913 etc., description of a detailed circuit structure is abbreviate | omitted. The inverter drive circuit is configured to turn on / off the plurality of semiconductor switches in the inverter circuit based on the output current of the inverter circuit and the tube voltage detected by the tube voltage detection unit 14 and fed back through the tube voltage control circuit 8 or the like. By controlling the output current, the output current and output voltage of the inverter circuit are controlled, and the power supplied to the X-ray tube 7 is controlled.

  The first winding 3 a of the winding transformer 3 is connected to the output side of the inverter 2. The second winding 3 b is connected to the input side of the main transformer 4 of the rotating unit 10. The winding transformer 3 is electromagnetically coupled by linking the magnetic fluxes of the first and second windings 3a and 3b, and the required power is contactlessly transferred from the fixed portion 9 side to the rotating portion 10 side. Deliver.

  The main transformer 4 boosts the AC voltage output from the inverter 2. The rectifier 5 and the smoothing capacitor 6 make the output voltage of the main transformer 4 a DC high voltage.

  The rotating plate of the rotating unit 10 further includes a tube voltage detecting unit 14, an anode rotation driving circuit 31, a filament heating circuit 32, a rotating side control circuit 30, a rotating side space transmission module 21, and A / D converters 11 and 13. It is installed.

  The anode rotation drive circuit 31 rotates the disk-type anode target of the X-ray tube 7. Thereby, the thermal electrons generated at the cathode collide with the anode target and disperse the energy of collision when X-rays are generated. The filament heating circuit 32 heats the cathode filament of the X-ray tube 7 and generates thermoelectrons.

  X-rays emitted from the X-ray tube 7 are irradiated onto the subject, and the X-rays that have passed through the subject are detected by the X-ray detector 12. The detection signal of the X-ray detector 12 is converted into a digital signal by the A / D converter 13 and transmitted from the rotation side space transmission module 21 to the stationary side space transmission module 20 of the fixed unit 9.

  The detection signal of the X-ray detector 12 received by the stationary side spatial transmission module 20 is subjected to image reconstruction processing or the like by the signal processing unit 22 to reconstruct a tomographic image of the subject.

  On the turntable of the rotating unit 10, a tube voltage detecting unit 14 for detecting a voltage (tube voltage) on both sides of the X-ray tube 7 and an A / D converter 11 are further mounted. The tube voltage detected by the tube voltage detector 14 is converted into a digital signal by the A / D conversion circuit 11 and converted into a serial signal by the rotation side control circuit 30. At this time, in the present embodiment, the rotation-side control circuit 30 records the time T0 when the A / D converter 11 starts the A / D conversion of the tube voltage signal.

  The rotation side space transmission module 21 receives the A / D converted tube voltage signal and the signal indicating the time T 0 from the rotation side control circuit 30 and transmits them to the stationary side space transmission module 20. The rotation-side space transmission module 21 also transmits the X-ray detection signal output from the X-ray detector 12 to the stationary-side space transmission module 20.

  The stationary side space transmission module 20 separates the tube voltage signal and the information signal at time T0 from the received signal and feeds back to the inverter 2 via the tube voltage control circuit 8. Among the received signals, the X-ray detection signal is transferred to the signal processing device 22.

  The feedback of the tube voltage is accompanied by a time delay because optical transmission, electrostatic transmission, or spatial transmission using radio waves is performed between the stationary unit 9 and the rotating unit 10 by the rotation-side spatial transmission module 21 and the stationary-side spatial transmission module 20. Therefore, in the inverter control circuit 8, a dead time of 1 ms to several ms is generated for the feedback of the tube voltage.

  In addition, signals related to the operation of these circuits, such as operation start signals and abnormality signals of the anode rotation drive circuit 31 and the filament heating circuit 32, are also converted into serial signals via the rotation side control circuit 30, and are stationary by the rotation side spatial transmission module 30. It transmits and receives to and from the spatial transmission module 20.

  The dead time due to the transmission delay of the stationary-side spatial transmission module 20 and the rotation-side spatial transmission module 21 includes a correction protocol for errors that occur during transmission, and thus varies rather than being constant. For example, methods such as a parity check, a sum check, and a CRC check are used to detect a transmission error.

  Next, the tube voltage control circuit 8 is a control system using a Smith predictor 80 as shown in FIG. 2 in order to compensate for the dead time and fluctuations of the dead time accompanying the feedback of the tube voltage.

  As shown in FIG. 2, the tube voltage control circuit 8 includes a controller 82 that performs PI control, a Smith predictor 80, and a time delay calculation circuit 85. The main circuit 100 of the control target 102 of the tube voltage control circuit 8 includes the winding transformer 3, the main transformer 4, the rectifier 5, and the smoothing capacitor 6 shown in FIG. A circuit including the main circuit 100, the A / D converter 11, the rotation-side control circuit 30, the rotation-side space transmission module 21, and the stationary-side space transmission module 20 is the control object 102 of the tube voltage control circuit 8.

The transfer function of the control target 102 is G (s), but includes a ^dead time L (delay time, transfer function e ^−sL ) that cannot be ignored. ^Therefore , the transfer function of the control target 102 is expressed as G (s) e ^−sL. Is done. In addition, since the dead time L includes the error correction protocol by the stationary side space transmission module 20 and the rotation side space transmission module 21 as described above, the dead time L is not constant and varies.

The Smith predictor 80 includes a control target model circuit 81 and a dead time model circuit 84. The control target model circuit 81 has a transfer function P (s) substantially equal to the transfer function G (s) of the control target 102, and the ^dead time model circuit 84 has a transfer function e ^−sL equal to the ^dead time element. Specific configurations of the model circuits 81 and 84 will be described later.

The tube voltage control circuit 8 transmits the feedback 90 and the dead time model 104 via the transfer function P (s) of the control target model 81 to the controller 82 (transfer function Gc (s)) by the Smith method. A feedback 86 of a difference 88 between the function e ^−sL and the transfer function G (s) e ^−sL of the control target 102 is performed. Thereby, the controller 82 controls the control object 102 (transfer function G (s) e ^−sL ) having a ^{dead time} . The disturbance 87 is zero (d = 0). That is, the controller 82 always predicts the phenomenon that appears after the lapse of the dead time by the control target model circuit 81 and the dead time model circuit 84 by the Smith method, while controlling the control amount (difference 88), the set value R (s), and the controller. The operation amount U (s) is calculated from the transfer function C (s) of 101.

  When the transfer function P (s) of the controlled object model circuit 81 is equal to the transfer function G (s) of the controlled object 102 and the dead time L of the dead time model circuit 84 is equal to the dead time L of the controlled object 102 The transfer function from the control command value R (s) to the output Y (s) of the feedback control system composed of the tube voltage control circuit 8 and the control object 102 is apparent from the above-described (Expression 3) and (Expression 4). As described above, since the dead time L does not remain, it is stable. Therefore, the tube voltage can be stably feedback controlled.

  At this time, it is necessary to construct a circuit in which the transfer function P (s) is equal to the transfer function G (s) of the control object 102 as the control target model circuit 81, and the dead time model circuit 84 is used as a dead time. It is necessary to use a value where L is equal to the dead time L of the control target 102.

  However, since the controlled object 102 includes the diode rectifier circuit 5 that is a non-linear element, it is difficult to obtain the transfer function of the controlled object 102. Therefore, in this embodiment, a control target model circuit 81 having the same response characteristics as the main circuit 100 of the control target 102 is constructed and mounted. For example, the control target model circuit 81 is configured by an analog computer using an operational amplifier circuit, or a hardware circuit such as a programmable LSI including an FPGA (Field Programmable Gate Array).

  By configuring the non-linear element included in the main circuit 100 with an analog computer (op-amp circuit) or the like, the diode rectifier circuit that is a non-linear circuit can be directly incorporated in the control target model circuit 81. For this reason, the accuracy of the output signal of the control target model circuit 81 can be increased.

  In addition, since the response characteristic of the main circuit 100 of the control target 102 is reproduced by the operational amplifier circuit, the output signal of the control target model circuit 81 includes a dead time generated in the main circuit 100. As a result, the dead time generated in the main circuit 100 can be compensated by the control target model circuit 81. In addition, the operation of the control target model circuit 81 can be speeded up by configuring with an operational amplifier circuit. A specific configuration of the control target model circuit 81 will be described later.

  Other configurations of the tube voltage control circuit 8 excluding the control target model circuit 81 (the controller 82, the dead time model circuit 84, and the time delay calculation circuit 85 in the dotted line frame 83 in FIG. 2) are configured by a CPU and a memory. The CPU executes predetermined software in the memory to execute the operation of the above configuration.

  On the other hand, the dead time model circuit 84 needs to calculate a transfer function using a dead time L equal to the dead time L of the control target 102. The output signal of the control target model circuit 81 includes a dead time generated in the main circuit 100. Therefore, the dead time model circuit 84 calculates the dead time L generated in the circuit 110 (A / D converter 11 to stationary space transmission module 20) excluding the main circuit 100 of the controlled object 102 as shown in FIG. That's fine. However, the dead time L generated between the A / D converter 11 and the stationary side spatial transmission module 20 is not constant because the error correction protocol by the stationary side spatial transmission module 20 and the rotation side spatial transmission module 21 is also included. fluctuate.

  Therefore, in this embodiment, the time delay calculation circuit 85 calculates the dead time L including fluctuation due to error correction or the like as shown in the flow of FIG.

  That is, in the present embodiment, the rotation side control circuit 30 is configured to record the time T0 when the A / D converter 11 starts A / D conversion of the tube voltage signal (step 501). The rotation-side space transmission module 21 receives the A / D converted tube voltage signal and the signal indicating the information at time T0 from the rotation-side control circuit 30, and transmits them to the stationary-side space transmission module 20 (step 502). The stationary side space transmission module 20 receives this, separates the tube voltage signal and the time T0 from the received signal, and feeds back to the tube voltage control circuit 8 (step 503).

  The time delay calculation circuit 85 receives a signal indicating the time T0 from the stationary side space transmission module 20, and the difference L0 (= T1-T0) from the time T1 received by the time delay calculation circuit 85 from the stationary side space transmission module 20 ) Is calculated (step 504). Thereby, the dead time L0 generated in the circuit 110 from the A / D converter 11 to the stationary side space transmission module 20 is calculated.

  The time delay calculation circuit 85 calculates a dead time of the main circuit 100 that cannot be compensated for by the control target model circuit 81 or a dead time L1 (a constant value) generated by the time delay calculation circuit 85 itself, which has been obtained by calculation in advance. If necessary, the dead time L (= L0 + L1) is obtained by adding to L0 (step 505). The obtained dead time L is transferred to the dead time model circuit 84.

The ^dead time model circuit 84 is a circuit of the transfer function e ^{−sL and incorporates} the ^dead time L calculated by the time delay calculation circuit 85 into the feedback.

  In addition, the time which the rotation side control circuit 30 and the time delay calculating circuit 85 refer is synchronized.

  As described above, in this embodiment, since the dead time L that fluctuates with the transmission of the tube voltage signal can be obtained by calculation, the tube voltage can be accurately controlled using the Smith method.

  Next, a detailed configuration of the control target model circuit 81 will be described below. In the present embodiment, the control target model circuit 81 is configured by an operational amplifier circuit having response characteristics equal to those of the main circuit 100.

  First, an equivalent circuit of the main circuit 100 is shown in FIG. As shown in FIG. 4, the equivalent circuit of the tube voltage control circuit shows from the output voltage vs of the inverter 2 to the voltage vdc across the X-ray tube 7. For simplification, the X-ray tube 7 portion in the equivalent circuit is replaced with a resistor Rx. In order to configure the control target model circuit 81, the equivalent circuit of FIG. 4 is configured by an analog circuit using an operational amplifier.

  First, the capacitor in the equivalent circuit of FIG. 4 is replaced with the analog circuit of the operational amplifier of FIG. 5A, and the reactor portion is replaced with the analog circuit of the operational amplifier of FIG. 5B.

The magnifications of the equivalent circuit voltage sensor 600 and current sensor 700 are set to 1/2000 and 1/10000, respectively. Thereby, the impedance ratio Kz between the control object model circuit 81 and the equivalent circuit of FIG. 4 can be calculated as follows.
... (Formula 5)

  Thus, since the impedance ratio is 5, the impedance in the equivalent circuit of FIG. The input voltage (inverter 2 output voltage) vs and the input current is (inverter 2 output current) of the equivalent circuit are measurable values. In the model circuit 81, these values are taken in and calculated. An X-ray tube voltage predicted value vdc is obtained and output.

  Here, the equivalent circuit of FIG. 4 is divided into three circuit parts (a first equivalent circuit 201, a second equivalent circuit 202, and a third equivalent circuit 203) as shown in FIG. 6, and a model circuit for each is designed. FIG. 7 shows a first equivalent circuit 201 that is an equivalent circuit, and FIG. 8 shows a model circuit in which the first equivalent circuit 201 is configured by an operational amplifier. First, voltage drops vcs, vrs, and vlsr at Cs, Rs, and Lsr of the first equivalent circuit 201 are calculated, and the sum vlcr of these voltage drops is subtracted from the input voltage (inverter output voltage) vs. The voltage vx output from the first equivalent circuit 201 is obtained. For example, the voltage drop due to Cs is obtained by (Equation 6) in the equivalent circuit and by (Equation 7) in the model circuit.

... (Formula 6)
... (Formula 7)

Using the impedance ratio Kz, the capacitor and resistance corresponding to this circuit can be calculated as follows (Equation 8).
(Equation 8)

From (Equation 8), the resistance R1 is as shown in (Equation 9).
(Equation 9)

Here, assuming that C1 = 100 pF, R1 in FIG. 8 is obtained by (Equation 10) below.
(Equation 10)

  Hereinafter, similarly, the value of the resistance of the operational amplifier circuit is determined. FIG. 9 shows a second equivalent circuit 202 extracted from the equivalent circuit of FIG. 6, and FIG. 10 shows a model circuit in which the second equivalent circuit 202 of FIG. Similarly, FIG. 11 shows a third equivalent circuit 203 extracted from the equivalent circuit of FIG. 6, and FIG. 12 shows a model circuit in which the third equivalent circuit 203 of FIG.

  In the third equivalent circuit 203 of FIG. 11, the portion including the diode bridge 211 that is a non-linear load is used as it is on the model circuit with the impedance increased by a factor of five. Then, the voltages v to dc at the final stage of the third equivalent circuit 203 are used as the output of the control target model circuit 81.

  On the other hand, a diode in an electronic circuit has a dead region and a forward voltage drop of about 0.3V. That is, when the forward voltage applied between the anode and the cathode exceeds 0.3V, the current is turned on and current flows, and the voltage other than 0 to 0.3V does not turn on. Even in an actual equivalent circuit, there is a diode insensitive region, but the ratio between the diode in the electronic circuit and the diode in the power module is greatly different, which may cause an error in the model circuit.

  Therefore, in order to eliminate the influence of the insensitive area of the diode in the electronic circuit, the distance from the diode bridge 211 to the load of the model circuit in FIG. 12 is changed as shown in FIG. That is, the portion of the diode bridge 211 in FIG. 12 is replaced with an absolute value circuit 400 that is an output voltage of full-wave rectification, and a load circuit 500 that applies a peak hold circuit using a half-wave rectification circuit and a voltage follower circuit is added. As a result, the on / off state of the diode is reproduced. Therefore, since these compensation circuits become ideal diodes in the model circuit, no dead area is generated. Note that the forward voltage drop of the power module diode in the equivalent circuit can be corrected by subtraction before the absolute value circuit of the model circuit.

  As described above, the controlled object model circuit 81 configured by the operational amplifier circuit (analog computer) shown in FIGS. 8, 10, and 12 (partially replaced by FIG. 13) is obtained. This operational amplifier circuit is mounted on the control target model circuit 81 shown in FIG. Since the main circuit 100 includes the diode rectifier circuit 5 that is a non-linear element, it is difficult to obtain a transfer function. However, in this embodiment, a controlled object model having the same response characteristics as the main circuit 100 of the controlled object 102 is used. Since the circuit 81 can be constructed by an operational amplifier circuit, control using the Smith method is possible.

  A simulation was performed to confirm the performance of the tube voltage control system of this embodiment.

  The X-ray tube voltage is controlled to change to 570 V in a stepwise manner to approach the state of emitting X-rays. The X-ray tube voltage is controlled by using a phase shift inverter, and each gain such as PI control. Were simulated using the already adjusted ones.

  First, as a feedback system of the X-ray tube voltage control system of the comparative example, an ideal feedback (PI control) system time without an AD / DA converter, no error correction of spatial transmission, and no dead time. The response simulation result is shown in FIG. In FIG. 14, vdcref represents an X-ray tube voltage setting value, and vdc represents an X-ray tube voltage feedback value. As apparent from FIG. 14, since this feedback system has no dead time, the X-ray tube voltage follows the set value well.

  Next, as a comparative example, normal feedback control (PI control) without using the Smith predictor 80 as a feedback system having a certain dead time due to a delay due to spatial transmission in the control system and an AD / DA converter A simulation was performed when controlled by. Specifically, sampling by AD / DA conversion was set to 20 kHz, and dead time due to communication delay was set to 1 ms. The result is shown in FIG. In FIG. 15, vdcdelay is an X-ray tube voltage feedback value after a dead time element is added. As apparent from FIG. 15, the X-ray tube voltage vdc oscillates largely around the command value vdcref, and stable control cannot be performed. This seems to be caused by the large proportional gain of the X-ray tube voltage control. Thus, it can be seen that when the dead time is large, a stable response cannot be obtained only by the PI control.

  On the other hand, the simulation result of the time response at the time of applying the Smith predictor 80 of this embodiment to the X-ray tube voltage control system with the fixed dead time 1ms of the same conditions as FIG. 15 is shown. However, since the dead time is constant, the time delay calculation circuit 85 is not used, and the dead time L of the dead time model circuit 84 is reproduced by holding each time as a digital value. Further, the output of the above-described analog computer (op-amp circuit) is used for the control target model circuit 81. The simulation result is shown in FIG. When the Smith predictor 80 is used, the X-ray tube voltage response vdcdelay generates a delay time of 1 ms, but is almost the same as the response in the ideal state when there is no dead time, the X-ray tube voltage is set to the set value vdcref. It can be seen that the system follows well and is effective for a system with dead time.

  However, if there is a dead time and the dead time fluctuates due to an error correction operation or the like, even if the Smith predictor 80 is used, the fluctuation of the dead time due to transmission error correction as shown in FIG. Will become unstable and vibrate. (Note that the set value of the tube voltage is 50 kV unlike FIGS. 15 and 16.) Therefore, the dead time compensation function by the Smith predictor 80 cannot be stabilized.

  Therefore, when the time delay calculation circuit 85 of this embodiment is operated to compensate for the variation in the dead time, the result is as shown in FIG. Since it is possible to compensate not only for the fixed dead time generated in the tube voltage detection signal but also for the fluctuation of the dead time caused by error correction, it can be confirmed that the tube voltage vdc can always be controlled stably.

  Further, not only the above-described tube voltage output information and X-ray detection signal but also other information can be transmitted and received between the rotation-side space transmission module 21 and the stationary-side space transmission module 20 shown in FIG. . For example, an abnormal signal generated in the rotating unit 10.

  In the above-described embodiment, the controller 82 that performs PI control is configured by software. However, the present invention is not limited to this, and it may be configured by hardware using an analog circuit, FPGA (Field Programmable Gate Array), or the like. It is.

  Here, an example in which the dead time compensation apparatus is provided in the X-ray CT apparatus has been described. However, the time delay calculation circuit 85 and the Smith predictor 80 of the present embodiment can be used for other apparatuses in which the dead time fluctuates. It is.

As described above, the X-ray CT apparatus of the present embodiment feeds back tube voltage output information that requires real-time characteristics to the inverter using the serial signal space transmission means. This serial signal spatial transmission means has a spatial propagation delay and a delay time due to error correction ( ^dead time element e ^−sL ), and the time varies, but the time delay arithmetic circuit 85 and the Smith predictor 80 stabilize the operation. Therefore, it is possible to provide a highly reliable X-ray CT apparatus capable of obtaining the tube voltage characteristics.

  Further, by configuring a model circuit to be controlled including a nonlinear circuit and a nonlinear load with an analog computer (op-amp circuit), a Smith predictor can be realized without using a transfer function or a state equation. Therefore, as in the inverter control system of the X-ray CT apparatus, it is possible to stabilize the controlled object by the normal Smith method.

  In addition, this invention is not limited to the said Example, A various deformation | transformation implementation is possible within the range of the summary of this invention. For example, the non-linear element in the control target of the present embodiment is not limited to the diode rectifier circuit but may be a transistor circuit or the like.

(Second Embodiment)
In the first embodiment, the dead time L0 is obtained from the difference between the A / D conversion start time T0 and the reception time T1 of the time delay calculation circuit 85. However, in the second embodiment, the dead time L0 is obtained by another method. Ask for.

  When the characteristics of the spatial transmission modules 20 and 21 are known in advance, the dead time L0 can be obtained from the function of the number of retransmissions R associated with a transmission error and the function of the time Tr required for one retransmission. The time Tr required for one retransmission is a value determined by the characteristics of the spatial transmission modules 20 and 21 and can be obtained in advance.

  Therefore, in the second embodiment, the stationary-side spatial transmission module 20 counts the number of retransmissions R that accompanies a transmission error, and passes it to the time delay calculation circuit 85.

  The time delay calculation circuit 85 obtains L0 by the following (Equation 11) and obtains the dead time L by (Equation 12).

L0 = R * Tr (Formula 11)
L = L0 + L1 (12)
However, in (Equation 12), L1 is a dead time of the main circuit 100 that has been previously calculated by calculation and cannot be compensated for by the control target model circuit 81, or a time delay calculation circuit, as in the first embodiment. 85 is a dead time caused by itself, and is a constant value.

  Other configurations are the same as those of the first embodiment, and thus description thereof is omitted.

  In the configuration of the second embodiment, it is necessary to record the time T0 when the rotation side control circuit starts A / D conversion as in the first embodiment, and to transmit the time T0 information superimposed on the tube voltage information. In addition, there is an advantage that the dead time L can be calculated only by the operation of the stationary side transmission module 20 and the time delay calculation circuit 85 on the stationary side.

(Third embodiment)
In the third embodiment, the A / D converter 11 is configured to perform A / D conversion processing at a predetermined constant timing and interval. The rotation-side control circuit 30 does not record the time T0, but assigns consecutive numbers to the A / D converted tube voltage values, superimposes them on the tube voltage value data, and transmits them by the space transmission modules 20 and 21. .

  The time delay calculation circuit 85 calculates the time at which A / D conversion is started from the number superimposed on the tube voltage value data, and calculates L0 from the difference from the current time. A predetermined L1 is added to L0 to calculate the dead time L. L1 uses a predetermined value as in the first embodiment.

  According to the configuration of the third embodiment, since the rotation-side control circuit does not record the time T0 but assigns consecutive numbers, it is not necessary to use the time. For this reason, there is no need to synchronize the time of the clock function referred to by the rotation side control circuit and the time of the clock function referred to by the time delay calculation circuit, and there is an advantage that the configuration can be simplified.

  In the first to third embodiments described above, the inverter 2 is not included in the main circuit 100, but the inverter 2 is included in the main circuit 100, and an equivalent circuit of the main circuit 100 including the inverter 2 is configured by an operational amplifier circuit. It is also possible to use the control target model circuit 81. Since the inverter 2 has a non-linear element such as a diode rectifier circuit and an active circuit portion having a plurality of control modes, it is difficult to define a transfer function, but it is controlled by using an operational amplifier circuit as in this embodiment. The target model circuit 81 can be configured.

  In addition, the configuration of the dead time compensation of the present embodiment is not limited to the X-ray CT apparatus, but is an industrial system having dead time such as an A / D conversion circuit, a D / A conversion circuit, a sampling circuit, or a communication delay circuit. It can be applied to a frequently used digital control system.

1: power supply (DC voltage), 2: inverter, 3: winding transformer with non-contact power supply, 4: main transformer, 5: rectifier, 6: smoothing capacitor, 7: X-ray tube, 8: tube voltage control circuit , 9: stationary part, 10: rotating part, 11, 13: A / D conversion circuit, 14: tube voltage detecting part, 20: stationary side spatial transmission module, 21: rotational side spatial transmission module, 30: rotational side control circuit 80: Smith predictor 81: Control target model circuit 82: Controller 84: Dead time model circuit 85: Time delay arithmetic circuit 100: Main circuit 101: Controller 102: Control target 103: Control target Model: 104: Dead time model, 105: Smith predictor, 201: First equivalent circuit, 202: Second equivalent circuit, 203: Third equivalent circuit, 400: Absolute value circuit (full-wave rectifier circuit) 500: Load circuit 600: voltage sensor, 700: current sensor

  The present invention relates to a function for compensating a dead time of signal transmission and fluctuation thereof in an X-ray CT apparatus that controls a control target mounted on a rotating unit by a control circuit disposed in a stationary unit.

  In the X-ray CT apparatus, an X-ray tube and an X-ray detector are mounted on a rotating disk, and X-ray irradiation and detection are performed while rotating around the subject. For this reason, in order to supply power from the inverter circuit on the stationary side to the X-ray tube on the rotating disk and to pass the detection signal of the X-ray detector from the rotating disk to the stationary signal processing device, Electric power and signal transmission means are arranged at the contact portion between the two portions. For example, a transmission means combining a slip ring and a brush is widely known.

  In Patent Document 1, in order to solve the problem that wear occurs in the contact portion between the slip ring and the brush, coils are arranged on the opposing surfaces of the rotating disk and the stationary portion, and power is supplied in a non-contact manner by electromagnetic induction. Techniques to do this are disclosed.

  In paragraph 0019 of Patent Document 1, in addition to the slip ring and non-contact electromagnetic induction, the detection signal of the X-ray detector on the turntable is transmitted to the stationary part by a communication system using light or radio waves. Is described.

  Further, the control circuit of the inverter circuit of the stationary part is controlled so as to obtain a predetermined X-ray output by feeding back the tube voltage of the X-ray tube on the rotating disk. For this reason, the tube voltage signal is transmitted to the stationary part by a slip ring, non-contact electromagnetic induction, a communication system using light or radio waves.

  On the other hand, in a plant such as a thermal power plant, PID control is generally used when controlling the flow rate of fuel supplied to a boiler. The Smith method is used because feedback control becomes difficult when there is a large delay (dead time) until a response is detected from the control target after changing the control amount to the control target. For example, Patent Document 2 uses a Smith predictor for controlling the steam temperature of a boiler. The technique of Patent Document 2 calculates the dead time using an autoregressive model in order to prevent the steam temperature from being emitted when there is a fluctuation in the dead time. Further, Patent Document 3 obtains a change in the gain ratio from the output of the control target model means in order to sufficiently exert the function of the Smith method even when the characteristics and gain of the control target change in plant control, and control is performed. A technique for correcting the gain of a signal is disclosed.

Here, a general feedback control system and the Smith method will be briefly described. A normal feedback control system is shown in FIG. In FIG. 19, C (s) is a transfer function of the controller 101, G (s) is a transfer function of the controlled object 102, e- ^sL is a transfer function of a ^dead time element, R (s) is a control command, U (s) Indicates an operation amount, D (s) indicates a disturbance, and Y (s) indicates an output. In this feedback control system, when the control object 102 is only the first-order delay and there is almost no dead time L (L≈0), it can be easily controlled by PI control. However, when the dead time of the control object 102 is large, the control is greatly affected and the control becomes difficult. The transfer function of the control system in FIG. 19 at that time is expressed as shown in (Equation 1) below.

... (Formula 1)
However, no disturbance is considered (D (s) = 0). From the above equation 1, the characteristic equation of this control system is expressed as the following equation 2.

... (Formula 2)

  Since this characteristic equation includes the dead time L, when L is a size that cannot be ignored, the control performance is degraded, and the controller 101 is difficult to design.

Therefore, in order to compensate for this dead time, the Smith method is used in the conventional plant control as disclosed in Patent Documents 2 and 3. A basic configuration diagram of a control system using the Smith method is shown in FIG. In FIG. 20, the control target model 103 has a transfer function P (s) substantially equal to the transfer function G (s) of the control target 102, and the ^dead time model 104 has a transfer function e ^−sL equal to the ^dead time element. . The controlled object model 103 and the dead time model 104 are collectively referred to as a Smith predictor 105.

As shown in FIG. 20, the control system using the Smith method ^{feeds back} the transfer function P (s) of the control target model 103 to the control target 102 (transfer function G (s) e ^−sL ) having a ^{dead time.} In addition, the ^difference between the transfer function e ^{−sL of the dead} time model 104 and the transfer function G (s) e ^−sL of the control target 102 is fed back. That is, the Smith method has a control target model 103 and a dead time model 104, and performs control while always predicting a phenomenon that appears after the dead time. That is, the manipulated variable U (s) is calculated from the controlled variable, the set value R (s), and the transfer function C (s) of the controller 101, and the change of the controlled variable with respect to the manipulated variable U (s) is changed using the Smith predictor. Further, an operation amount U (s) is calculated in the controller C (s) based on the amount of change. Therefore, the transfer function from the control command value R (s) to the output Y (s) of the feedback control system provided with the Smith predictor 105 of FIG.

... (Formula 3)

If there is no error between the transfer function of the control target model 103 and the transfer function of the control target 102, that is, if P (s) = G (s), the characteristic equation is as shown in (Expression 4).
(Formula 4)
The characteristic equation of (Equation 4) is stable because the dead time L does not remain. By using the Smith predictor in this way, the influence of dead time can be eliminated from the system, and the output Y (s) can accurately follow the control command R (s). Moreover, the same controller 101 as when there is no dead time can be used.

  The Smith method eliminates wasted time from the control loop, which eliminates the wasted time in the control target, and eliminates the wasted time from the characteristic equation of the feedback control system. On the other hand, it is known that it has a feature such that it is left as it is complicated because the dead time remains as it is.

Japanese Patent No. 4008010 JP-A-62-248902 JP-A-5-35306

  In the X-ray CT apparatus, tube voltage information of the X-ray tube is fed back by a communication system such as an optical fiber, thereby controlling the power supplied to the X-ray tube by controlling the frequency and output voltage of the inverter. Since the X-ray tube is mounted on the rotating disk, when the tube voltage information is fed back to the stationary inverter circuit, transmission from the rotating disk to the stationary side is required. For transmission, slip ring, optical transmission, electrostatic transmission, radio wave, etc. are used. However, since transmission involves transmission from the rotating disk to the stationary side during transmission, a time delay (dead time) of 1 ms to several ms occurs. . In particular, when digital transmission is performed, information can be transmitted with high accuracy by error detection processing of transmitted data, error correction processing when an error is found, and the like. Time) and transmission delay (variation of dead time) occurs.

  Also, preparing an independent transmission path for transmission of tube voltage information leads to an increase in the size and cost of the apparatus. For this reason, it is conceivable to transmit the tube voltage signal using the transmission path of the X-ray detection data of the X-ray detector. In this case, since it is necessary to estimate the transmission timing of the X-ray detection data and transmit the tube voltage signal in the meantime, the variation in the waste time and the waste time becomes large.

  It is conceivable to apply the techniques described in Patent Documents 2 and 3 that use the Smith method to control a plant with a large dead time to an X-ray CT apparatus to control an inverter circuit using tube voltage information with a large dead time. . However, as described above, the Smith predictor requires a controlled object model having a transfer function equal to the controlled object and a dead time model having a transfer function equal to the dead time. An apparatus that generates a high voltage, such as an X-ray CT apparatus, includes a diode rectifier circuit that is a non-linear element in the controlled object, so that the controlled object is expressed by a transfer function or state equation required by the Smith predictor. It is difficult to create a model. In addition, since the variation in the dead time is unknown, it is difficult to create a dead time model.

  Patent Document 2 discloses a configuration for calculating the waste time of the steam temperature signal of the boiler when the fuel flow control valve to the boiler is controlled by using an autoregressive model. It is not possible to detect dead time and variations in dead time due to error detection, error correction processing, and the like during transmission of tube voltage digital data.

  The objective of this invention is providing the X-ray CT apparatus which can compensate the fluctuation | variation of the waste time of a control object, and a waste time.

  In order to achieve the above object, according to the present invention, the following X-ray CT apparatus is provided. That is, the X-ray CT apparatus includes an X-ray irradiation unit and an X-ray detection unit, a rotating unit that rotates around the subject, a power supply unit that supplies power to the X-ray irradiation unit, and a stationary unit that includes a control unit. And a transmission unit that transmits a signal from the rotating unit to the stationary unit. The control unit performs feedback control of the power supply unit using the information of the X-ray irradiation unit transmitted from the rotating unit to the stationary unit by the transmission unit. The control unit calculates a delay time caused by a Smith predictor including a control target model circuit and a dead time model circuit, and transmission of information of the X-ray irradiation unit by a transmission unit, and compensates for a dead time of the dead time model circuit A time calculation unit.

  For example, when the transmission unit is configured to perform digital transmission having an error correction function, the delay time includes a delay time caused by error correction by the error correction function.

  For example, the rotation unit is configured to include a rotation-side control unit that detects information of the X-ray irradiation unit and superimposes information indicating the time before transmission by the transmission unit and transmits the information to the transmission unit. In this case, the delay time calculation unit can calculate the delay time by obtaining the difference between the time superimposed on the information transmitted by the transmission unit and the time after transmission.

  In addition, for example, the rotation unit is configured to include a rotation-side control unit that detects the information of the X-ray irradiation unit and superimposes information indicating a number at a predetermined timing and transmits the information to the transmission unit. In this case, the delay time calculation unit can calculate the delay time from the number superimposed on the information transmitted by the transmission unit.

  Further, for example, the delay time calculation unit can receive the number of error corrections from the transmission unit and calculate the delay time using the number of error corrections and a predetermined time required for error correction.

  The control target model circuit can be configured by, for example, an operational amplifier circuit or a programmable integrated circuit equivalent to the control target.

According to another aspect of the present invention, there is provided a dead time compensation device that performs feedback control of a control target having a dead time . This dead time compensator calculates a delay time calculation that compensates for a dead time of a dead time model circuit by calculating a delay time generated in signal transmission from the controlled object model circuit and a Smith predictor including the dead time model circuit and a controlled object. A part.

  According to the present invention, even when a delay time occurs in the signal transmission from the rotating part to the stationary part and the delay time fluctuates, the delay time is calculated and the dead time of the dead time model circuit is calculated. Can be compensated. Therefore, even an apparatus that requires signal transmission between the rotating part and the stationary part, such as an X-ray CT apparatus, can perform highly accurate control.

1 is a block diagram showing a schematic configuration of a contactless power feeding type X-ray CT apparatus of an embodiment. The block diagram which shows the control system of the tube voltage of the X-ray CT apparatus of FIG. The flowchart which shows the calculation processing procedure of the dead time by the control system of FIG. The circuit diagram which shows the equivalent circuit of the tube voltage control circuit from the output of the inverter 2 of embodiment to the X-ray tube 7. FIG. The circuit diagram which shows the integration circuit using an operational amplifier. The circuit diagram which shows the differentiation circuit using an operational amplifier. The circuit diagram which shows the equivalent circuit which divided the equivalent circuit of FIG. 4 into three. The circuit diagram which took out the 1st equivalent circuit of the equivalent circuit divided | segmented in FIG. FIG. 8 is a model circuit diagram illustrating the first equivalent circuit of FIG. 7 by an operational amplifier circuit. The circuit diagram which extracted the 2nd equivalent circuit of the equivalent circuit divided | segmented in FIG. FIG. 10 is a model circuit diagram illustrating the second equivalent circuit of FIG. 9 as an operational amplifier circuit. The circuit diagram which extracted the 3rd equivalent circuit of the equivalent circuit divided | segmented in FIG. The model circuit diagram represented with the operational amplifier circuit of the 3rd equivalent circuit of FIG. FIG. 13 is an operational amplifier circuit diagram for compensating for a diode forward voltage drop of a diode bridge in the circuit of FIG. 12. The graph which shows the simulation result of the time response at the time of carrying out PI control of the ideal X-ray tube voltage control system with no dead time of a comparative example. The graph which shows the simulation result of the time response at the time of carrying out PI control of the X-ray tube voltage control system with the dead time of 1 ms of a comparative example. The graph which shows the simulation result of the time response at the time of applying the Smith predictor 80 to a fixed X-ray tube voltage control system with dead time 1ms. The graph which shows the simulation result of the time response at the time of applying the Smith predictor 80 to the X-ray tube voltage control system in which dead time fluctuates. The graph which shows the simulation result of the time response at the time of applying the tube voltage control circuit 8 provided with the Smith predictor 80 of this embodiment and the time delay calculating circuit 85 to the X-ray tube voltage control system in which dead time fluctuates. The block diagram which shows a general feedback control system. The block diagram which shows the control system of a general Smith method.

  Hereinafter, an X-ray CT apparatus according to an embodiment of the present invention will be described.

(First embodiment)
FIG. 1 shows an outline of the non-contact power feeding type X-ray CT apparatus of the first embodiment. As shown in FIG. 1, this X-ray CT apparatus includes a power source 1, an inverter 2, a winding transformer 3 by non-contact power feeding, a main transformer 4, a rectifier 5, a smoothing capacitor 6, and an X-ray tube. 7, a tube voltage control circuit 8, an X-ray detector 12, a signal processing unit 22, an anode rotation drive circuit 31, and a filament heating circuit 32.

  The X-ray tube 7, the main transformer 4, the rectifier 5, the smoothing capacitor 6, and the X-ray detector 12 are mounted on a rotating disk (not shown) that rotates around the subject and constitutes a rotating unit 10. Both the power source 1 and the inverter 2 are configured as a stationary part 9.

  At the position where the stationary frame on the stationary part 9 side and the rotating disk of the rotating part 10 face each other, the first winding 3a and the second winding 3b are arranged so that the magnetic fluxes are linked to each other. The winding transformer 3 to perform is comprised.

  In addition, a rotation side space transmission module 21 is mounted on the turntable of the rotation unit 10, and a stationary side space transmission module 20 is disposed on the fixed unit 9. These are communication systems that transmit information from the rotating unit 10 to the fixed unit 9 and use optical communication, electrostatic transmission, or communication systems using radio waves.

  The power source 1 of the stationary part 9 generates a DC voltage. The inverter 2 includes an inverter circuit and an inverter drive circuit, and converts the DC voltage output from the power source 1 into AC. About the structure of an inverter circuit and an inverter drive circuit, since it is a well-known structure described in Unexamined-Japanese-Patent No. 2005-94913 etc., description of a detailed circuit structure is abbreviate | omitted. The inverter drive circuit is configured to turn on / off the plurality of semiconductor switches in the inverter circuit based on the output current of the inverter circuit and the tube voltage detected by the tube voltage detection unit 14 and fed back through the tube voltage control circuit 8 or the like. By controlling the output current, the output current and output voltage of the inverter circuit are controlled, and the power supplied to the X-ray tube 7 is controlled.

  The first winding 3 a of the winding transformer 3 is connected to the output side of the inverter 2. The second winding 3 b is connected to the input side of the main transformer 4 of the rotating unit 10. The winding transformer 3 is electromagnetically coupled by linking the magnetic fluxes of the first and second windings 3a and 3b, and the required power is contactlessly transferred from the fixed portion 9 side to the rotating portion 10 side. Deliver.

  The main transformer 4 boosts the AC voltage output from the inverter 2. The rectifier 5 and the smoothing capacitor 6 make the output voltage of the main transformer 4 a DC high voltage.

  The rotating plate of the rotating unit 10 further includes a tube voltage detecting unit 14, an anode rotation driving circuit 31, a filament heating circuit 32, a rotating side control circuit 30, a rotating side space transmission module 21, and A / D converters 11 and 13. It is installed.

  The anode rotation drive circuit 31 rotates the disk-type anode target of the X-ray tube 7. Thereby, the thermal electrons generated at the cathode collide with the anode target and disperse the energy of collision when X-rays are generated. The filament heating circuit 32 heats the cathode filament of the X-ray tube 7 and generates thermoelectrons.

  X-rays emitted from the X-ray tube 7 are irradiated onto the subject, and the X-rays that have passed through the subject are detected by the X-ray detector 12. The detection signal of the X-ray detector 12 is converted into a digital signal by the A / D converter 13 and transmitted from the rotation side space transmission module 21 to the stationary side space transmission module 20 of the fixed unit 9.

  The detection signal of the X-ray detector 12 received by the stationary side spatial transmission module 20 is subjected to image reconstruction processing or the like by the signal processing unit 22 to reconstruct a tomographic image of the subject.

  On the turntable of the rotating unit 10, a tube voltage detecting unit 14 for detecting a voltage (tube voltage) on both sides of the X-ray tube 7 and an A / D converter 11 are further mounted. The tube voltage detected by the tube voltage detector 14 is converted into a digital signal by the A / D conversion circuit 11 and converted into a serial signal by the rotation side control circuit 30. At this time, in the present embodiment, the rotation-side control circuit 30 records the time T0 when the A / D converter 11 starts the A / D conversion of the tube voltage signal.

  The rotation side space transmission module 21 receives the A / D converted tube voltage signal and the signal indicating the time T 0 from the rotation side control circuit 30 and transmits them to the stationary side space transmission module 20. The rotation-side space transmission module 21 also transmits the X-ray detection signal output from the X-ray detector 12 to the stationary-side space transmission module 20.

  The stationary side space transmission module 20 separates the tube voltage signal and the information signal at time T0 from the received signal and feeds back to the inverter 2 via the tube voltage control circuit 8. Among the received signals, the X-ray detection signal is transferred to the signal processing device 22.

  The feedback of the tube voltage is accompanied by a time delay because optical transmission, electrostatic transmission, or spatial transmission using radio waves is performed between the stationary unit 9 and the rotating unit 10 by the rotation-side spatial transmission module 21 and the stationary-side spatial transmission module 20. Therefore, in the inverter control circuit 8, a dead time of 1 ms to several ms is generated for the feedback of the tube voltage.

  In addition, signals related to the operation of these circuits, such as operation start signals and abnormality signals of the anode rotation drive circuit 31 and the filament heating circuit 32, are also converted into serial signals via the rotation side control circuit 30, and are stationary by the rotation side spatial transmission module 30. It transmits and receives to and from the spatial transmission module 20.

  The dead time due to the transmission delay of the stationary-side spatial transmission module 20 and the rotation-side spatial transmission module 21 includes a correction protocol for errors that occur during transmission, and thus varies rather than being constant. For example, methods such as a parity check, a sum check, and a CRC check are used to detect a transmission error.

  Next, the tube voltage control circuit 8 is a control system using a Smith predictor 80 as shown in FIG. 2 in order to compensate for the dead time and fluctuations of the dead time accompanying the feedback of the tube voltage.

  As shown in FIG. 2, the tube voltage control circuit 8 includes a controller 82 that performs PI control, a Smith predictor 80, and a time delay calculation circuit 85. The main circuit 100 of the control target 102 of the tube voltage control circuit 8 includes the winding transformer 3, the main transformer 4, the rectifier 5, and the smoothing capacitor 6 shown in FIG. A circuit including the main circuit 100, the A / D converter 11, the rotation-side control circuit 30, the rotation-side space transmission module 21, and the stationary-side space transmission module 20 is the control object 102 of the tube voltage control circuit 8.

The transfer function of the control target 102 is G (s), but includes a ^dead time L (delay time, transfer function e ^−sL ) that cannot be ignored. ^Therefore , the transfer function of the control target 102 is expressed as G (s) e ^−sL. Is done. In addition, since the dead time L includes the error correction protocol by the stationary side space transmission module 20 and the rotation side space transmission module 21 as described above, the dead time L is not constant and varies.

The Smith predictor 80 includes a control target model circuit 81 and a dead time model circuit 84. The control target model circuit 81 has a transfer function P (s) substantially equal to the transfer function G (s) of the control target 102, and the ^dead time model circuit 84 has a transfer function e ^−sL equal to the ^dead time element. Specific configurations of the model circuits 81 and 84 will be described later.

The tube voltage control circuit 8 transmits the feedback 90 and the dead time model 104 via the transfer function P (s) of the control target model 81 to the controller 82 (transfer function Gc (s)) by the Smith method. A feedback 86 of a difference 88 between the function e ^−sL and the transfer function G (s) e ^−sL of the control target 102 is performed. Thereby, the controller 82 controls the control object 102 (transfer function G (s) e ^−sL ) having a ^{dead time} . The disturbance 87 is zero (d = 0). That is, the controller 82 always predicts the phenomenon that appears after the lapse of the dead time by the control target model circuit 81 and the dead time model circuit 84 by the Smith method, while controlling the control amount (difference 88), the set value R (s), and the controller. The operation amount U (s) is calculated from the transfer function C (s) of 101.

  When the transfer function P (s) of the controlled object model circuit 81 is equal to the transfer function G (s) of the controlled object 102 and the dead time L of the dead time model circuit 84 is equal to the dead time L of the controlled object 102 The transfer function from the control command value R (s) to the output Y (s) of the feedback control system composed of the tube voltage control circuit 8 and the control object 102 is apparent from the above-described (Expression 3) and (Expression 4). As described above, since the dead time L does not remain, it is stable. Therefore, the tube voltage can be stably feedback controlled.

  At this time, it is necessary to construct a circuit in which the transfer function P (s) is equal to the transfer function G (s) of the control object 102 as the control target model circuit 81, and the dead time model circuit 84 is used as a dead time. It is necessary to use a value where L is equal to the dead time L of the control target 102.

  However, since the controlled object 102 includes the diode rectifier circuit 5 that is a non-linear element, it is difficult to obtain the transfer function of the controlled object 102. Therefore, in this embodiment, a control target model circuit 81 having the same response characteristics as the main circuit 100 of the control target 102 is constructed and mounted. For example, the control target model circuit 81 is configured by an analog computer using an operational amplifier circuit, or a hardware circuit such as a programmable LSI including an FPGA (Field Programmable Gate Array).

  By configuring the non-linear element included in the main circuit 100 with an analog computer (op-amp circuit) or the like, the diode rectifier circuit that is a non-linear circuit can be directly incorporated in the control target model circuit 81. For this reason, the accuracy of the output signal of the control target model circuit 81 can be increased.

  In addition, since the response characteristic of the main circuit 100 of the control target 102 is reproduced by the operational amplifier circuit, the output signal of the control target model circuit 81 includes a dead time generated in the main circuit 100. As a result, the dead time generated in the main circuit 100 can be compensated by the control target model circuit 81. In addition, the operation of the control target model circuit 81 can be speeded up by configuring with an operational amplifier circuit. A specific configuration of the control target model circuit 81 will be described later.

  Other configurations of the tube voltage control circuit 8 excluding the control target model circuit 81 (the controller 82, the dead time model circuit 84, and the time delay calculation circuit 85 in the dotted line frame 83 in FIG. 2) are configured by a CPU and a memory. The CPU executes predetermined software in the memory to execute the operation of the above configuration.

  On the other hand, the dead time model circuit 84 needs to calculate a transfer function using a dead time L equal to the dead time L of the control target 102. The output signal of the control target model circuit 81 includes a dead time generated in the main circuit 100. Therefore, the dead time model circuit 84 calculates the dead time L generated in the circuit 110 (A / D converter 11 to stationary space transmission module 20) excluding the main circuit 100 of the controlled object 102 as shown in FIG. That's fine. However, the dead time L generated between the A / D converter 11 and the stationary side spatial transmission module 20 is not constant because the error correction protocol by the stationary side spatial transmission module 20 and the rotation side spatial transmission module 21 is also included. fluctuate.

  Therefore, in this embodiment, the time delay calculation circuit 85 calculates the dead time L including fluctuation due to error correction or the like as shown in the flow of FIG.

  That is, in the present embodiment, the rotation side control circuit 30 is configured to record the time T0 when the A / D converter 11 starts A / D conversion of the tube voltage signal (step 501). The rotation-side space transmission module 21 receives the A / D converted tube voltage signal and the signal indicating the information at time T0 from the rotation-side control circuit 30, and transmits them to the stationary-side space transmission module 20 (step 502). The stationary side space transmission module 20 receives this, separates the tube voltage signal and the time T0 from the received signal, and feeds back to the tube voltage control circuit 8 (step 503).

  The time delay calculation circuit 85 receives a signal indicating the time T0 from the stationary side space transmission module 20, and the difference L0 (= T1-T0) from the time T1 received by the time delay calculation circuit 85 from the stationary side space transmission module 20 ) Is calculated (step 504). Thereby, the dead time L0 generated in the circuit 110 from the A / D converter 11 to the stationary side space transmission module 20 is calculated.

  The time delay calculation circuit 85 calculates a dead time of the main circuit 100 that cannot be compensated for by the control target model circuit 81 or a dead time L1 (a constant value) generated by the time delay calculation circuit 85 itself, which has been obtained by calculation in advance. If necessary, the dead time L (= L0 + L1) is obtained by adding to L0 (step 505). The obtained dead time L is transferred to the dead time model circuit 84.

The ^dead time model circuit 84 is a circuit of the transfer function e ^{−sL and incorporates} the ^dead time L calculated by the time delay calculation circuit 85 into the feedback.

  In addition, the time which the rotation side control circuit 30 and the time delay calculating circuit 85 refer is synchronized.

  As described above, in this embodiment, since the dead time L that fluctuates with the transmission of the tube voltage signal can be obtained by calculation, the tube voltage can be accurately controlled using the Smith method.

  Next, a detailed configuration of the control target model circuit 81 will be described below. In the present embodiment, the control target model circuit 81 is configured by an operational amplifier circuit having response characteristics equal to those of the main circuit 100.

  First, an equivalent circuit of the main circuit 100 is shown in FIG. As shown in FIG. 4, the equivalent circuit of the tube voltage control circuit shows from the output voltage vs of the inverter 2 to the voltage vdc across the X-ray tube 7. For simplification, the X-ray tube 7 portion in the equivalent circuit is replaced with a resistor Rx. In order to configure the control target model circuit 81, the equivalent circuit of FIG. 4 is configured by an analog circuit using an operational amplifier.

  First, the capacitor in the equivalent circuit of FIG. 4 is replaced with the analog circuit of the operational amplifier of FIG. 5A, and the reactor portion is replaced with the analog circuit of the operational amplifier of FIG. 5B.

The magnifications of the equivalent circuit voltage sensor 600 and current sensor 700 are set to 1/2000 and 1/10000, respectively. Thereby, the impedance ratio Kz between the control object model circuit 81 and the equivalent circuit of FIG. 4 can be calculated as follows.
... (Formula 5)

  Thus, since the impedance ratio is 5, the impedance in the equivalent circuit of FIG. The input voltage (inverter 2 output voltage) vs and the input current is (inverter 2 output current) of the equivalent circuit are measurable values. In the model circuit 81, these values are taken in and calculated. An X-ray tube voltage predicted value vdc is obtained and output.

  Here, the equivalent circuit of FIG. 4 is divided into three circuit parts (a first equivalent circuit 201, a second equivalent circuit 202, and a third equivalent circuit 203) as shown in FIG. 6, and a model circuit for each is designed. FIG. 7 shows a first equivalent circuit 201 that is an equivalent circuit, and FIG. 8 shows a model circuit in which the first equivalent circuit 201 is configured by an operational amplifier. First, voltage drops vcs, vrs, and vlsr at Cs, Rs, and Lsr of the first equivalent circuit 201 are calculated, and the sum vlcr of these voltage drops is subtracted from the input voltage (inverter output voltage) vs. The voltage vx output from the first equivalent circuit 201 is obtained. For example, the voltage drop due to Cs is obtained by (Equation 6) in the equivalent circuit and by (Equation 7) in the model circuit.

... (Formula 6)
... (Formula 7)

Using the impedance ratio Kz, the capacitor and resistance corresponding to this circuit can be calculated as follows (Equation 8).
(Equation 8)

From (Equation 8), the resistance R1 is as shown in (Equation 9).
(Equation 9)

Here, assuming that C1 = 100 pF, R1 in FIG. 8 is obtained by (Equation 10) below.
(Equation 10)

  Hereinafter, similarly, the value of the resistance of the operational amplifier circuit is determined. FIG. 9 shows a second equivalent circuit 202 extracted from the equivalent circuit of FIG. 6, and FIG. 10 shows a model circuit in which the second equivalent circuit 202 of FIG. Similarly, FIG. 11 shows a third equivalent circuit 203 extracted from the equivalent circuit of FIG. 6, and FIG. 12 shows a model circuit in which the third equivalent circuit 203 of FIG.

  In the third equivalent circuit 203 of FIG. 11, the portion including the diode bridge 211 that is a non-linear load is used as it is on the model circuit with the impedance increased by a factor of five. Then, the voltages v to dc at the final stage of the third equivalent circuit 203 are used as the output of the control target model circuit 81.

  On the other hand, a diode in an electronic circuit has a dead region and a forward voltage drop of about 0.3V. That is, when the forward voltage applied between the anode and the cathode exceeds 0.3V, the current is turned on and current flows, and the voltage other than 0 to 0.3V does not turn on. Even in an actual equivalent circuit, there is a diode insensitive region, but the ratio between the diode in the electronic circuit and the diode in the power module is greatly different, which may cause an error in the model circuit.

  Therefore, in order to eliminate the influence of the insensitive area of the diode in the electronic circuit, the distance from the diode bridge 211 to the load of the model circuit in FIG. 12 is changed as shown in FIG. That is, the portion of the diode bridge 211 in FIG. 12 is replaced with an absolute value circuit 400 that is an output voltage of full-wave rectification, and a load circuit 500 that applies a peak hold circuit using a half-wave rectification circuit and a voltage follower circuit is added. As a result, the on / off state of the diode is reproduced. Therefore, since these compensation circuits become ideal diodes in the model circuit, no dead area is generated. Note that the forward voltage drop of the power module diode in the equivalent circuit can be corrected by subtraction before the absolute value circuit of the model circuit.

  As described above, the controlled object model circuit 81 configured by the operational amplifier circuit (analog computer) shown in FIGS. 8, 10, and 12 (partially replaced by FIG. 13) is obtained. This operational amplifier circuit is mounted on the control target model circuit 81 shown in FIG. Since the main circuit 100 includes the diode rectifier circuit 5 that is a non-linear element, it is difficult to obtain a transfer function. However, in this embodiment, a controlled object model having the same response characteristics as the main circuit 100 of the controlled object 102 is used. Since the circuit 81 can be constructed by an operational amplifier circuit, control using the Smith method is possible.

  A simulation was performed to confirm the performance of the tube voltage control system of this embodiment.

  The X-ray tube voltage is controlled to change to 570 V in a stepwise manner to approach the state of emitting X-rays. The X-ray tube voltage is controlled by using a phase shift inverter, and each gain such as PI control. Were simulated using the already adjusted ones.

  First, as a feedback system of the X-ray tube voltage control system of the comparative example, an ideal feedback (PI control) system time without an AD / DA converter, no error correction of spatial transmission, and no dead time. The response simulation result is shown in FIG. In FIG. 14, vdcref represents an X-ray tube voltage setting value, and vdc represents an X-ray tube voltage feedback value. As apparent from FIG. 14, since this feedback system has no dead time, the X-ray tube voltage follows the set value well.

  Next, as a comparative example, normal feedback control (PI control) without using the Smith predictor 80 as a feedback system having a certain dead time due to a delay due to spatial transmission in the control system and an AD / DA converter A simulation was performed when controlled by. Specifically, sampling by AD / DA conversion was set to 20 kHz, and dead time due to communication delay was set to 1 ms. The result is shown in FIG. In FIG. 15, vdcdelay is an X-ray tube voltage feedback value after a dead time element is added. As apparent from FIG. 15, the X-ray tube voltage vdc oscillates largely around the command value vdcref, and stable control cannot be performed. This seems to be caused by the large proportional gain of the X-ray tube voltage control. Thus, it can be seen that when the dead time is large, a stable response cannot be obtained only by the PI control.

  On the other hand, the simulation result of the time response at the time of applying the Smith predictor 80 of this embodiment to the X-ray tube voltage control system with the fixed dead time 1ms of the same conditions as FIG. 15 is shown. However, since the dead time is constant, the time delay calculation circuit 85 is not used, and the dead time L of the dead time model circuit 84 is reproduced by holding each time as a digital value. Further, the output of the above-described analog computer (op-amp circuit) is used for the control target model circuit 81. The simulation result is shown in FIG. When the Smith predictor 80 is used, the X-ray tube voltage response vdcdelay generates a delay time of 1 ms, but is almost the same as the response in the ideal state when there is no dead time, the X-ray tube voltage is set to the set value vdcref. It can be seen that the system follows well and is effective for a system with dead time.

  However, if there is a dead time and the dead time fluctuates due to an error correction operation or the like, even if the Smith predictor 80 is used, the fluctuation of the dead time due to transmission error correction as shown in FIG. Will become unstable and vibrate. (Note that the set value of the tube voltage is 50 kV unlike FIGS. 15 and 16.) Therefore, the dead time compensation function by the Smith predictor 80 cannot be stabilized.

  Therefore, when the time delay calculation circuit 85 of this embodiment is operated to compensate for the variation in the dead time, the result is as shown in FIG. Since it is possible to compensate not only for the fixed dead time generated in the tube voltage detection signal but also for the fluctuation of the dead time caused by error correction, it can be confirmed that the tube voltage vdc can always be controlled stably.

  Further, not only the above-described tube voltage output information and X-ray detection signal but also other information can be transmitted and received between the rotation-side space transmission module 21 and the stationary-side space transmission module 20 shown in FIG. . For example, an abnormal signal generated in the rotating unit 10.

  In the above-described embodiment, the controller 82 that performs PI control is configured by software. However, the present invention is not limited to this, and it may be configured by hardware using an analog circuit, FPGA (Field Programmable Gate Array), or the like. It is.

  Here, an example in which the dead time compensation apparatus is provided in the X-ray CT apparatus has been described. However, the time delay calculation circuit 85 and the Smith predictor 80 of the present embodiment can be used for other apparatuses in which the dead time fluctuates. It is.

As described above, the X-ray CT apparatus of the present embodiment feeds back tube voltage output information that requires real-time characteristics to the inverter using the serial signal space transmission means. This serial signal spatial transmission means has a spatial propagation delay and a delay time due to error correction ( ^dead time element e ^−sL ), and the time varies, but the time delay arithmetic circuit 85 and the Smith predictor 80 stabilize the operation. Therefore, it is possible to provide a highly reliable X-ray CT apparatus capable of obtaining the tube voltage characteristics.

  Further, by configuring a model circuit to be controlled including a nonlinear circuit and a nonlinear load with an analog computer (op-amp circuit), a Smith predictor can be realized without using a transfer function or a state equation. Therefore, as in the inverter control system of the X-ray CT apparatus, it is possible to stabilize the controlled object by the normal Smith method.

  In addition, this invention is not limited to the said Example, A various deformation | transformation implementation is possible within the range of the summary of this invention. For example, the non-linear element in the control target of the present embodiment is not limited to the diode rectifier circuit but may be a transistor circuit or the like.

(Second Embodiment)
In the first embodiment, the dead time L0 is obtained from the difference between the A / D conversion start time T0 and the reception time T1 of the time delay calculation circuit 85. However, in the second embodiment, the dead time L0 is obtained by another method. Ask for.

  When the characteristics of the spatial transmission modules 20 and 21 are known in advance, the dead time L0 can be obtained from the function of the number of retransmissions R associated with a transmission error and the function of the time Tr required for one retransmission. The time Tr required for one retransmission is a value determined by the characteristics of the spatial transmission modules 20 and 21 and can be obtained in advance.

  Therefore, in the second embodiment, the stationary-side spatial transmission module 20 counts the number of retransmissions R that accompanies a transmission error, and passes it to the time delay calculation circuit 85.

  The time delay calculation circuit 85 obtains L0 by the following (Equation 11) and obtains the dead time L by (Equation 12).

L0 = R * Tr (Formula 11)
L = L0 + L1 (12)
However, in (Equation 12), L1 is a dead time of the main circuit 100 that has been previously calculated by calculation and cannot be compensated for by the control target model circuit 81, or a time delay calculation circuit, as in the first embodiment. 85 is a dead time caused by itself, and is a constant value.

  Other configurations are the same as those of the first embodiment, and thus description thereof is omitted.

  In the configuration of the second embodiment, it is necessary to record the time T0 when the rotation side control circuit starts A / D conversion as in the first embodiment, and to transmit the time T0 information superimposed on the tube voltage information. In addition, there is an advantage that the dead time L can be calculated only by the operation of the stationary side transmission module 20 and the time delay calculation circuit 85 on the stationary side.

(Third embodiment)
In the third embodiment, the A / D converter 11 is configured to perform A / D conversion processing at a predetermined constant timing and interval. The rotation-side control circuit 30 does not record the time T0, but assigns consecutive numbers to the A / D converted tube voltage values, superimposes them on the tube voltage value data, and transmits them by the space transmission modules 20 and 21. .

  The time delay calculation circuit 85 calculates the time at which A / D conversion is started from the number superimposed on the tube voltage value data, and calculates L0 from the difference from the current time. A predetermined L1 is added to L0 to calculate the dead time L. L1 uses a predetermined value as in the first embodiment.

  According to the configuration of the third embodiment, since the rotation-side control circuit does not record the time T0 but assigns consecutive numbers, it is not necessary to use the time. For this reason, there is no need to synchronize the time of the clock function referred to by the rotation side control circuit and the time of the clock function referred to by the time delay calculation circuit, and there is an advantage that the configuration can be simplified.

  In the first to third embodiments described above, the inverter 2 is not included in the main circuit 100, but the inverter 2 is included in the main circuit 100, and an equivalent circuit of the main circuit 100 including the inverter 2 is configured by an operational amplifier circuit. It is also possible to use the control target model circuit 81. Since the inverter 2 has a non-linear element such as a diode rectifier circuit and an active circuit portion having a plurality of control modes, it is difficult to define a transfer function, but it is controlled by using an operational amplifier circuit as in this embodiment. The target model circuit 81 can be configured.

  In addition, the configuration of the dead time compensation of the present embodiment is not limited to the X-ray CT apparatus, but is an industrial system having dead time such as an A / D conversion circuit, a D / A conversion circuit, a sampling circuit, or a communication delay circuit. It can be applied to a frequently used digital control system.

1: power supply (DC voltage), 2: inverter, 3: winding transformer with non-contact power supply, 4: main transformer, 5: rectifier, 6: smoothing capacitor, 7: X-ray tube, 8: tube voltage control circuit , 9: stationary part, 10: rotating part, 11, 13: A / D conversion circuit, 14: tube voltage detecting part, 20: stationary side spatial transmission module, 21: rotational side spatial transmission module, 30: rotational side control circuit 80: Smith predictor 81: Control target model circuit 82: Controller 84: Dead time model circuit 85: Time delay arithmetic circuit 100: Main circuit 101: Controller 102: Control target 103: Control target Model: 104: Dead time model, 105: Smith predictor, 201: First equivalent circuit, 202: Second equivalent circuit, 203: Third equivalent circuit, 400: Absolute value circuit (full-wave rectifier circuit) 500: Load circuit 600: voltage sensor, 700: current sensor

Claims (7)

A rotating unit that mounts an X-ray irradiation unit and an X-ray detection unit and rotates around the subject, a stationary unit including a power supply unit and a control unit that supplies power to the X-ray irradiation unit, and the rotation unit A transmission unit for transmitting a signal to the stationary unit,
The control unit includes a control target model circuit and a dead time model circuit for feedback control of the power supply unit using the information of the X-ray irradiation unit transmitted from the rotation unit to the stationary unit by the transmission unit. A delay time calculation unit that calculates a delay time caused by transmission of information of the X-ray irradiation unit by the transmission unit and compensates for a dead time of the dead time model circuit. X-ray CT system. The X-ray CT apparatus according to claim 1, wherein the transmission unit performs digital transmission having an error correction function,
The X-ray CT apparatus, wherein the delay time includes a delay time caused by error correction by an error correction function. 2. The X-ray CT apparatus according to claim 1, wherein the rotation unit detects the information of the X-ray irradiation unit, and superimposes information indicating a time before transmission by the transmission unit on the information. A rotation-side control unit for transmission to the unit,
The X-ray CT apparatus, wherein the delay time calculation unit calculates a delay time by obtaining a difference between the time superimposed on the information transmitted by the transmission unit and a time after transmission. The X-ray CT apparatus according to claim 1, wherein the rotation unit detects the information of the X-ray irradiation unit and superimposes information representing a number at a predetermined timing on the information and transmits the information to the transmission unit. Equipped with a rotating side control unit,
The X-ray CT apparatus, wherein the delay time calculation unit calculates a delay time from the number superimposed on the information transmitted by the transmission unit.   3. The X-ray CT apparatus according to claim 2, wherein the delay time calculation unit receives the number of error corrections from the transmission unit, and uses the error correction number and a predetermined time required for error correction to delay time. X-ray CT apparatus characterized by calculating   2. The X-ray CT apparatus according to claim 1, wherein the control target model circuit is configured by an operational amplifier circuit or a programmable integrated circuit equivalent to the control target. A control device having a dead time compensation function for feedback control of a control target having a dead time,
A Smith predictor including a control target model circuit and a dead time model circuit; and a delay time calculation unit that calculates a delay time generated in signal transmission from the control target and compensates for the dead time of the dead time model circuit. The control apparatus provided with the dead time compensation function characterized by this.