JP4772198B2 - Magnetic resonance imaging system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a noise generation location specifying device used in a magnetic resonance imaging (MRI) apparatus, and a magnetic resonance imaging system using the noise generation location specification device.
[0002]
[Prior art]
In a hospital, for example, a magnetic resonance imaging system (hereinafter also referred to as an MRI system) that images a test site of a subject using magnetic resonance is provided.
FIG. 10 is a diagram for explaining a conventional MRI system 100.
As shown in FIG. 10, the MRI system 100 includes an operation room / machine room 101 and a scan room 102.
The operation room / machine room 101 includes a cradle control device 120, a display control device 121, an RF (Radio Frequency) transmission coil drive device 122, a gradient coil drive device 123, an RF reception coil drive device 124, an operator console 125, and a power supply device. 126 is arranged.
In the scan room 102, a cradle driving device 140, a display device 150, and a magnet system 160 are disposed.
The operation room / machine room 101 and the scan room 102 are partitioned by a wall 110, and an electromagnetic wave filter 111 is incorporated in the wall 110.
[0003]
Based on the control signal input from the operator console 125 via the control transmission line 127, the power supply device 126 is based on the cradle control device 120, the display control device 121, the RF transmission coil drive device 122, the gradient coil drive device 123, Power is supplied to the RF receiving coil driving device 124 via the power transmission lines 128_0 to 128_5, respectively.
[0004]
The cradle control device 120 operates by the power received via the power transmission line 128_0, and drives the cradle in the cradle driving device 140 based on the control signal received from the operator console 125 via the control transmission line 129_0. The power is supplied to the unit 141 via the power transmission line 130_0, and a control signal is output via the control transmission line 131_0.
[0005]
The display control device 121 operates by the power received through the power transmission line 128_1, and based on the control signal received from the operator console 125 through the control transmission line 129_1, the display unit 151 in the display device 150. In addition, power is supplied through the power transmission line 130_1 and a control signal is output through the control transmission line 131_1.
[0006]
The RF transmission coil driving device 122 is operated by the power received via the power transmission line 128_2, and based on the control signal received from the operator console 125 via the control transmission line 129_2, Power is supplied to the transmission coil driver 161 via the power transmission line 130_2, and a control signal is output via the control transmission line 131_2.
[0007]
The gradient coil driving device 123 is operated by the power received through the power transmission line 128_3, and based on the control signal received from the operator console 125 through the control transmission line 129_3, the gradient coil in the magnet system 160 is provided. Power is supplied to the driver 162 via the power transmission line 130_3, and a control signal is output via the control transmission line 131_3.
[0008]
The RF receiver coil driving device 124 operates by the power received via the power transmission line 128_4, and based on the control signal received from the operator console 125 via the control transmission line 129_4, Power is supplied to the receiving coil driver 163 through the power transmission line 130_4, and a control signal is output through the control transmission line 131_4.
[0009]
For example, the operator console 125 generates a control signal generated in accordance with an operator's operation via the control transmission lines 132_0 to 132_4, respectively, a cradle driving unit 141, a display unit 151, an RF transmission coil driving unit 161, and a gradient coil. The data is output to the driving unit 162 and the RF receiving coil driving unit 163.
[0010]
By the way, in the conventional MRI system 100 as shown in FIG. 10, the power supply device 126, the cradle control device 120, the display control device 121, the RF transmission coil driving device 122, the gradient coil driving device 123, the control transmission lines 127, 129_0. 129_5, 131_0 to 131_4, 132_0 to 132_4, power transmission lines 130_0 to 130_4, cradle driving unit 141, display unit 151, RF transmission coil driving unit 161, gradient coil driving unit 162 or RF receiving coil driving unit 163 are noise generation sources. Such noise may be received by the RF receiving coil.
In addition, a cooling device provided in the operation room / machine room 101 or the scan room 102 may be a noise generation source.
Such noise adversely affects the image when the operator console 125 performs image reconstruction using the electromagnetic wave received by the RF receiving coil.
[0011]
For this reason, conventionally, when noise that adversely affects an image occurs, a person in charge of service goes to the hospital and identifies the noise generation source based on past experience and the like.
[0012]
[Problems to be solved by the invention]
However, in the conventional method described above, the burden on the service person when noise occurs is large, and it takes a long time to specify the noise generation source.
[0013]
The present invention has been made in view of the above-described problems of the prior art, and uses a noise generation location identification device that can easily identify noise that adversely affects the operation of a magnetic resonance imaging system in a short time, and the noise occurrence location identification device. An object of the present invention is to provide a magnetic resonance imaging system.
[0014]
[Means for Solving the Problems]
In order to solve the above-described problems of the prior art and achieve the above-described object, the noise generation location specifying device of the first invention includes one or a plurality of electronic circuits, and a high frequency is applied to the subject in the static magnetic field space. A magnetic resonance imaging apparatus that forms a magnetic field and generates a magnetic resonance signal by receiving an electromagnetic wave generated by a spin excited from a subject by a receiving coil, a power supply apparatus, and a power supply from the power supply apparatus One or a plurality of signal power supply devices that transmit at least one of power and control signals toward the electronic component, and at least one of the power and control signals transmitted from the signal power supply device are transmitted to the electronic circuit. A noise occurrence location identifying device for identifying a noise occurrence location of a magnetic resonance imaging system having one or a plurality of transmission lines that are on the transmission line Switching that is arranged at the end of the transmission line and switches whether or not to supply at least one of the power and the control signal sent from the signal power supply device to a part or the whole of the transmission line based on the selection signal A circuit, and a control device that generates the selection signal and identifies a noise generation location based on the selection signal and the detection result of the reception coil.
[0015]
The operation of the noise occurrence location specifying device of the first invention is as follows.
The control device generates a selection signal and outputs it to the switching circuit.
Whether the switching circuit supplies at least one of the power and control signal sent from the signal power supply device to a part or the whole of the transmission line in a predetermined pattern based on the selection signal input from the control device Set.
In the control device, the presence or absence of noise is detected using the electromagnetic wave received by the receiving coil of the magnetic resonance imaging apparatus.
The control device identifies the noise occurrence location based on the control content used when the noise is detected.
[0016]
According to a second aspect of the present invention, there is provided a noise generation location specifying device, which is disposed in a first region, includes one or a plurality of electronic circuits, forms a high frequency magnetic field in a subject in a static magnetic field space, and is excited from the subject. A magnetic resonance imaging apparatus for obtaining a magnetic resonance signal by receiving a generated electromagnetic wave generated by a receiving coil; a power supply apparatus disposed in a second area; and the power supply apparatus disposed in the second area. One or a plurality of signal power supply devices that receive power supply from the device and send at least one of power and a control signal toward the corresponding electronic component, and the corresponding signal disposed in the first region One or a plurality of first transmission lines for transmitting at least one of the power and control signal sent from the power supply device, and disposed in the magnetic resonance imaging apparatus or adjacent to the magnetic resonance imaging apparatus; Generation of noise in a magnetic resonance imaging system having one or a plurality of second transmission lines for transmitting at least one of power and control signals transmitted through the transmission line to the corresponding electronic circuit A location specifying device that sets whether or not to transmit at least one of the power and the control signal transmitted from the signal power supply device to the first transmission line corresponding to the signal power supply device. A switching circuit, and at least one of the power and the control signal transmitted through the first transmission line is transmitted to the second transmission line corresponding to the first transmission line. 2 switching circuit and the signal power supply device sends at least one of power and a control signal toward the electronic component corresponding to the signal power supply device Whether control, and a control device for controlling said first switching circuit and said second switching circuit the setting.
[0017]
The operation of the noise occurrence location specifying device of the second invention is as follows.
The control device controls whether or not the signal power supply device sends at least one of electric power and a control signal toward the electronic component corresponding to the signal power supply device, and the first switching circuit and the second switching device. Controls circuit settings.
Thereby, the power and control signal are transmitted by the signal power supply device, and the first switching circuit and the second switching circuit are set.
In the control device, the presence or absence of noise is detected using the electromagnetic wave received by the receiving coil of the magnetic resonance imaging apparatus.
For example, the control device identifies a noise occurrence location based on the content of control used when noise is detected.
[0018]
In the noise occurrence location specifying device according to the second aspect of the invention, preferably, when noise occurs, the control device determines the location of the noise based on the contents of the control and the reception result of the reception coil. Identify.
[0019]
In addition, the noise occurrence location specifying device of the second invention preferably further includes a third transmission line for supplying at least one of power and a control signal to the receiving coil irrespective of the control by the control device. .
[0020]
In the noise occurrence location specifying device according to the second aspect of the invention, preferably, the control device is a predetermined single unit that sends at least one of the power and the control signal from the signal power supply device to the electronic circuit. Alternatively, by using a plurality of combination patterns in order, the signal power supply device controls whether or not to send at least one of power and a control signal toward the electronic component corresponding to the signal power supply device, and the power and When the setting of the first switching circuit is controlled so that a control signal is not sent to the first transmission line, when the receiving coil detects noise, the combination pattern used when the noise is detected is used. It is determined that the corresponding signal power supply device or the first transmission line is a cause of noise.
[0021]
In the noise occurrence location specifying device according to the second aspect of the invention, preferably, the control device controls transmission of at least one of the power and the control signal by the signal power supply device using all the combination patterns. When the receiving coil does not detect noise, the first switching is sequentially performed by using a predetermined combination pattern or patterns that prescribe a first transmission line for transmitting at least one of power and a control signal. When the setting of the circuit is controlled, and the setting of the second switching circuit is controlled so that the power and control signal are not transmitted to the second transmission line, the receiving coil detects noise, It is determined that the first transmission line corresponding to the combination pattern used when the noise is detected is the cause of the noise.
[0022]
In the noise generation location specifying device according to the second aspect of the invention, preferably, the reception coil generates noise even when the control device controls the setting of the first switching circuit using all the combination patterns. If not, controlling the setting of the second switching circuit sequentially using a predetermined combination pattern or patterns that define a second transmission line for transmitting at least one of power and control signal; When the receiving coil detects noise, the second transmission line corresponding to the combination pattern used when the noise is detected or the electronic circuit corresponding to the second transmission line is determined to have a cause of noise. .
[0023]
In addition, the noise occurrence location specifying device according to the second invention is preferably configured such that the magnetic resonance imaging system performs one or more processing devices that perform processing used for the examination of the subject using the magnetic resonance imaging device. One or a plurality of signal power supply devices for a processing device that receive power supply from the power supply device and send at least one of power and a control signal toward an electronic component in the corresponding processing device; and the signal power supply In the case of further comprising one or a plurality of processing device transmission lines that transmit at least one of the power and control signal sent from the device toward the electronic circuit in the processing device, the noise occurrence location specifying device, Arranged on the processing equipment transmission line or at the end of the processing equipment transmission line, to a part or the whole of the processing equipment transmission line A processing device switching circuit for switching presence / absence of supply of at least one of the power and the control signal sent from the processing device signal power supply device based on the processing device selection signal; A selection signal is generated, and a noise generation location is specified based on the selection signal for the processing device and the detection result of the receiving coil.
[0024]
The magnetic resonance imaging system of the third invention is disposed in the first region, includes one or more electronic circuits, forms a high-frequency magnetic field in the subject in the static magnetic field space, and is excited from the subject. A magnetic resonance imaging apparatus for receiving a magnetic resonance signal by receiving an electromagnetic wave generated by a spin by a receiving coil, and the magnetic resonance image apparatus which is disposed in the second region, receives power supply, and is based on the first selection signal One or more signal power supply devices for determining whether or not to send at least one of power and control signals to corresponding electronic components in the resonance imaging device, and a first selection disposed in the second region A power supply device that determines whether or not to supply power to the signal power supply device based on a signal; and a power and a control signal that are disposed in the first region and are sent from the corresponding signal power supply device At least one of One or a plurality of first transmission lines that are arranged in the magnetic resonance imaging apparatus or adjacent to the magnetic resonance imaging apparatus, and at least power and control signals transmitted through the first transmission line. One or more second transmission lines for transmitting one to the corresponding electronic circuit and at least one of the power and control signal supplied from the signal power supply device based on the second selection signal, A first switching circuit that determines whether or not to transmit to the first transmission line corresponding to the signal power supply device, and the first transmission line based on the third selection signal, is transmitted A second switching circuit for determining whether or not to transmit at least one of electric power and a control signal to the second transmission line corresponding to the first transmission line, and the second switching circuit; Serial first selection signal, and a control device for generating the second selection signal and the third selection signal.
[0025]
In the magnetic resonance imaging system of the third invention, it is preferable that the control device, when noise occurs, the first selection signal, the second selection signal, the third selection signal, and The cause of the noise is identified based on the reception result of the reception coil.
[0026]
In the magnetic resonance imaging system according to the third aspect of the present invention, preferably, the power and control signal of the receiving coil are supplied to the receiving coil irrespective of the first selection signal, the second selection signal, and the third selection signal. It further has a third transmission line for supplying at least one.
[0027]
In the magnetic resonance imaging system according to the third aspect of the present invention, preferably, one or a plurality of processing devices that perform processing used for examination of the subject using the magnetic resonance imaging device, and supply of power from the power supply device In response, one or a plurality of signal power supply devices for a processing device that send at least one of power and a control signal toward an electronic component in the corresponding processing device, and the power and control sent from the signal power supply device One or a plurality of processing device transmission lines that transmit at least one of the signals toward an electronic circuit in the processing device, and disposed on the processing device transmission line or at an end of the processing device transmission line; Supply of at least one of the power and the control signal sent from the processing device signal power supply device to a part or the whole of the processing device transmission line. A processing device switching circuit for switching the presence or absence of the processing device based on the processing device selection signal, wherein the control device generates the processing device selection signal and detects the processing device selection signal and the receiving coil. Based on the result, the noise occurrence location is specified.
[0028]
In addition, the magnetic resonance imaging system of the third invention preferably further includes an electromagnetic wave shielding member that partitions the first region and the second region.
[0029]
In the magnetic resonance imaging system of the fourth invention, preferably, the second area has a third area and a fourth area partitioned by an electromagnetic wave shielding member, and the power supply device and the signal power The supply device is disposed in the third region, and the control device is disposed in the fourth region.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a diagram for explaining the arrangement of components of an MRI system according to an embodiment of the present invention, and FIG. 2 is an external view of a magnet system 12 and an operator console 15.
As shown in FIG. 1, the MRI system 1 is disposed in a scan room 2, a machine room 3, and an operation room 4.
As shown in FIGS. 1 and 2, a magnet system 12 of the MRI apparatus 10 is disposed in the scan room 2, and a cradle driving device 11 and a display device 14 are disposed in the vicinity of the MRI apparatus 10. ing.
The operation room 4 is provided with an operator console 15 operated by an operator 12.
In the machine room 3, a cradle control device 20, a display control device 21, an RF transmission coil driving device 22, a gradient coil driving device 23, an RF receiving coil driving device 24 and a power supply device 26 are disposed.
[0031]
The scan room 2, the machine room 3, and the operation room 4 are partitioned by a wall 5.
A door 6 and a window 7 are provided at a portion of the wall 5 that partitions the scan room 2 and the operation room 4.
The machine room 3 and the operation room 4 are partitioned by a wall 8.
An electromagnetic wave filter is incorporated in the wall 5, the door 6 and the wall 8.
[0032]
Here, the cradle control device 20, the display control device 21, the RF transmission coil driving device 22, the gradient coil driving device 23, and the RF receiving coil driving device 24 correspond to the signal power supply device of the present invention.
Further, the cradle control device 20 and the display control device 21 further correspond to the processing device signal power supply device of the present invention.
The MRI apparatus 10 corresponds to the magnetic resonance imaging apparatus of the present invention, and the operator console 15 corresponds to the control apparatus of the present invention.
The scan room 2 corresponds to the first area of the present invention, and the machine room 3 and the operation room 4 correspond to the second area of the present invention.
[0033]
[Magnet system 12]
FIG. 3 is a diagram for explaining the magnet system 12.
As shown in FIG. 3, the magnet system 12 includes magnet portions 91a and 91b, gradient coil portions 92a and 92b, RF coil portions 93a and 93b, an RF transmission coil driving portion 61, a gradient coil driving portion 62, and an RF receiving coil driving portion. 63, and a switching circuit 83.
Magnet portions 91a and 91b, gradient coil portions 92a and 92b, and RF coil portions 93a and 93b are located on both sides of the space 94 in the bore of the magnet system 12 from the outside toward the inside.
The magnet portions 91a and 91b are located opposite to each other with the space 94 where the subject 13 is located at the time of examination, and are, for example, permanent magnets. The magnet portions 91 a and 91 b form a static magnetic field in the space 94.
[0034]
The gradient coil portions 92a and 92b are located opposite to each other with the space 94 interposed therebetween.
The gradient coil units 92a and 92b have three systems in order to give the magnetic resonance signals received by the RF coil units 93a and 93b three-dimensional position information, and the gradient coil units 92a and 92b provide gradients to the strength of the static magnetic field formed by the magnet units 91a and 91b. A gradient magnetic field is generated.
[0035]
The RF coil portions 93a and 93b are located opposite to each other with the space 94 interposed therebetween.
A high frequency magnetic field for exciting spins in the body of the subject 13 is formed in the static magnetic field space 94 formed by the RF coil portions 93a and 93b and the magnet portions 91a and 91b. Here, the formation of a high-frequency magnetic field is called transmission of an RF excitation signal. The RF coil units 93a and 93b receive electromagnetic waves generated by excited spins as magnetic resonance signals. The RF coil sections 93a and 93b have a transmission coil and a reception coil (not shown). As the transmission coil and the reception coil, either the same coil or a dedicated coil is used.
[0036]
The RF transmission coil driving unit 61 receives supply of power through the power transmission line 36_2, and sends a drive signal to the RF coil units 91a and 91b based on the control signal received through the control transmission lines 37_2 and 38_2. An RF excitation signal is generated to excite spins in the body of the subject 13.
In the present embodiment, the power transmission line and the control transmission line are both electric wires.
[0037]
The gradient coil drive unit 62 is supplied with power through the power transmission line 36_3, and supplies a drive signal to the gradient coil units 92a and 92b based on the control signal received through the control transmission lines 37_3 and 38_3. To generate a gradient magnetic field. The gradient coil drive unit 62 has three systems of drive circuits (not shown) corresponding to the three systems of coils of the gradient coil units 92a and 92b.
[0038]
The RF receiving coil driving unit 63 receives power supplied through the power transmission line 30_4, and received by the RF coil units 93a and 93b based on the control signal received through the control transmission lines 31_4 and 32_4. The signal is captured, collected as view data, and output to the operator console 15.
[0039]
As will be described later, the switching circuit 83 is connected between the power transmission lines 33_2 and 36_2 and between the control transmission lines 34_2 and 37_2 based on a selection signal input from the operator console 15 via the control transmission line 71. Between the control transmission lines 35_2 and 38_2, between the power transmission lines 33_3 and 36_3, between the control transmission lines 34_3 and 37_3, and between the control transmission lines 35_3 and 38_3. Set to one of the connection states.
[0040]
[Cradle drive 11]
The cradle driving device 11 moves the cradle 90 in the Z and Y directions, drives the cradle 90, carries the subject 13 placed on the cradle 90 into the space 94 in the bore of the magnet system 12, and the space 94 The subject 13 is carried out from the above.
[0041]
[Display device 14]
The display device 14 is disposed, for example, at a position visible from the subject 13 and displays an image such as an operator's face.
Further, the display device 14 is provided with a speaker that outputs a voice uttered by an operator and a microphone that inputs a voice uttered by the subject 13.
[0042]
[Operator console 15]
FIG. 4 is a configuration diagram of the operator console 15.
As shown in FIG. 4, the operator console 15 includes a data processing unit 96, an operation unit 97, and an operation display unit 98.
For example, based on the operation signal from the operation unit 97, the data processing unit 96 transmits a control signal via the control transmission lines 27, 28_0 to 28_5, 32_0 to 32_4, 70, 71.
The data processing unit 96 reconstructs image data using view data (view data) input from the RF receiving coil driving unit 63 shown in FIG. 3 and outputs a display signal corresponding to the image data to the operation display unit 98. To do.
[0043]
The operation unit 97 is, for example, a keyboard or a mouse, and outputs an operation signal corresponding to the operation of the operator to the data processing unit 96.
The operation display unit 98 displays an image corresponding to the display signal input from the data processing unit 96 on the screen.
[0044]
Hereinafter, the power supply device 26, the cradle control device 20, the display control device 21, the RF transmission coil drive device 22, the gradient coil drive device 23, the RF reception coil drive device 24, the power supply device 26, the cradle drive device 11, the magnet system 12, and the display A power transmission line, a control transmission line, and a switching circuit for setting the connection state of each line disposed between the apparatus 14 and the apparatus 14 will be described.
In the present embodiment, the configuration illustrated in FIG. 5 is illustrated as an example of the present invention, but the configuration of the present invention is not limited to that illustrated in FIG.
FIG. 5 is a diagram for explaining a power transmission line, a control transmission line, and a switching circuit for setting a connection state of each line provided in the MRI system 1.
[0045]
In FIG. 5, the cradle driving device 11, the display device 14, and the magnet system 12 correspond to the processing device of the present invention, and the cradle driving portion 41, the display portion 51, the RF transmission coil driving portion 61, the gradient coil driving portion 62, and the RF reception. The coil driving unit 63 corresponds to the electronic circuit of the present invention.
The switching circuits 80, 81, 82 and 83 correspond to the switching circuit of the present invention.
The switching circuit 80 corresponds to the first switching circuit of the present invention, and the switching circuits 81, 82, and 83 correspond to the second switching circuit of the present invention.
The control transmission lines 29_0 to 29_4, 31_0 to 31_3, 32_0 to 32_3, 34_0 to 34_3, 35_0 to 35_3, 71, 72, 73, and 32_4 correspond to the transmission lines that transmit the control signal of the present invention.
The power transmission lines 28_0 to 28_5, 30_0 to 30_4, 33_0 to 33_3, and 36_0 to 36_3 correspond to the transmission lines for transmitting the power of the present invention.
[0046]
As shown in FIG. 5, a control transmission line 27 is disposed between the operator console 15 and the power supply device 26.
Control transmission lines 29_0 to 29_4 are arranged between the operator console 15, the cradle control device 20, the display control device 21, the RF transmission coil driving device 22, the gradient coil driving device 23, and the RF receiving coil driving device 24, respectively. It is installed.
Control transmission lines 32_0 to 32_3 and 70 are arranged between the operator console 15 and the switching circuit 80.
A control transmission line 71 is disposed between the operator console 15 and the switching circuit 81.
A control transmission line 72 is disposed between the operator console 15 and the switching circuit 82.
A control transmission line 73 is disposed between the operator console 15 and the switching circuit 83.
[0047]
Control transmission lines 31_0 to 31_3 are disposed between the switching circuit 80, the cradle control device 20, the display control device 21, the RF transmission coil driving device 22, and the gradient coil driving device 23, respectively.
For example, the switching circuit 80 is incorporated in the wall 5, and the electromagnetic wave filter 10 is incorporated in the wall 5.
[0048]
Further, power transmission is performed between the power supply device 26, the cradle control device 20, the display control device 21, the RF transmission coil driving device 22, the gradient coil driving device 23, the RF receiving coil driving device 24, and the operator console 15, respectively. Lines 28_0 to 28_5 are provided.
Further, power transmission lines 30_0 to 30_3 are arranged between the switching circuit 80, the cradle control device 20, the display control device 21, the RF transmission coil driving device 22, and the gradient coil driving device 23, respectively.
Further, a power transmission line 30_4 and a control transmission line 31_4 are disposed between the RF receiving coil driving device 24 and the RF receiving coil driving unit 63.
[0049]
Further, a power transmission line 33_0 and control transmission lines 34_0 and 35_0 are disposed between the switching circuit 80 and the switching circuit 81 disposed in the cradle driving device 11.
Further, a power transmission line 33_1 and control transmission lines 34_1 and 35_1 are disposed between the switching circuit 80 and the switching circuit 82 disposed in the display device 14.
Between the switching circuit 80 and the switching circuit 83 disposed in the magnet system 12, power transmission lines 33_2 and 33_3 and control transmission lines 34_2, 35_2, 34_3, and 35_3 are disposed. .
[0050]
In addition, a switching circuit 81 and a cradle driving unit 41 are disposed in the cradle driving device 11.
Between the switching circuit 81 and the cradle driving unit 41, a power transmission line 36_0 and control transmission lines 37_0 and 38_0 are arranged.
The switching circuit 81 is based on the control signal received via the control transmission line 71, between the power transmission lines 33_0 and 36_0, between the control transmission lines 34_0 and 37_0, and between the control transmission lines 35_0 and 38_0. Is set to either a connected state or a disconnected state.
[0051]
In the display device 14, a switching circuit 82 and a display unit 51 are provided.
Between the switching circuit 82 and the display unit 51, a power transmission line 36_1 and control transmission lines 37_1 and 38_1 are disposed.
Based on the selection signal received via the control transmission line 72, the switching circuit 82 is connected between the power transmission lines 33_1 and 36_1, between the control transmission lines 34_1 and 37_1, and between the control transmission lines 35_1 and 38_1. Is set to either a connected state or a disconnected state.
[0052]
In the magnet system 12, a switching circuit 83, an RF transmission coil driving unit 61, a gradient coil driving unit 62, and an RF receiving coil driving unit 63 are disposed.
Between the switching circuit 83 and the RF transmission coil driving unit 61, a power transmission line 36_2 and control transmission lines 37_2 and 38_2 are disposed.
Based on the selection signal received via the control transmission line 73, the switching circuit 83 is connected between the power transmission lines 33_2 and 36_2, between the control transmission lines 34_2 and 37_2, and between the control transmission lines 35_2 and 38_2. Is set to either a connected state or a disconnected state.
[0053]
In addition, a power transmission line 36_3 and control transmission lines 37_3 and 38_3 are disposed between the switching circuit 83 and the gradient coil driving unit 62.
Based on the selection signal received via the control transmission line 73, the switching circuit 83 is connected between the power transmission lines 33_3 and 36_3, between the control transmission lines 34_3 and 37_3, and between the control transmission lines 35_3 and 38_3. Is set to either a connected state or a disconnected state.
[0054]
Hereinafter, an operation example of the MRI system 1 when specifying a noise occurrence location will be described.
6 to 8 are flowcharts for explaining the operation example.
Step ST1:
For example, when a noise trouble such as an effect of white noise occurring in an image of the inspection result occurs, the operator operates the operation unit 97 shown in FIGS. 2 and 4 to input a noise generation location specifying instruction.
Thereby, the operator console 15 performs the processing after step ST2 based on the operation signal input from the operation unit 97.
[0055]
Step ST2:
The operator console 15 outputs a control signal instructing setting to the non-connected state to the switching circuits 80, 81, 82, and 83 via the control transmission lines 70, 71, 72, and 73, respectively.
The switching circuits 80, 81, 82, 83 make all of the power transmission line and the control transmission line unconnected based on the control signal input from the operator console 15.
[0056]
Step ST3:
The operator console 15 has a plurality of predefined first combination patterns (forms) for supplying power from the power supply device 26 to the cradle control device 20, the display control device 21, the RF transmission coil drive device 22, and the gradient coil drive device 23. Among them, one first combination pattern is selected.
[0057]
In the first combination pattern, power is supplied from the power supply device 26 to at least one of the cradle control device 20, the display control device 21, the RF transmission coil driving device 22, and the gradient coil driving device 23 according to the first combination pattern. When noise is detected in the performed state, it is stipulated so that it is possible to specify which device or a power transmission line or a control transmission line connected to the device is a noise occurrence location.
Specifically, the first combination pattern defines a pattern that specifies that power is supplied only from the power supply device 26 to the cradle control device 20, and specifies that power is supplied only from the power supply device 26 to the display control device 21. There are a pattern that specifies that power is supplied only from the power supply device 26 to the RF transmission coil driving device 22, a pattern that specifies that power is supplied only from the power supply device 26 to the gradient coil driving device 23, and the like.
[0058]
Step ST4:
The operator console 15 outputs a selection signal indicating the first combination pattern selected in step ST3 to the power supply device 26 via the control transmission line 27.
The power supply device 26 supplies power to the cradle control device 20, the display control device 21, the RF transmission coil drive device 22, and the gradient coil drive device 23 through the power transmission lines 28_0 to 28_5, respectively, based on the input selection signal. To do.
At this time, power is supplied from the power supply device 26 to the RF receiving coil driving device 24 and the operator console 15 via the power transmission lines 28_4 and 28_5 regardless of the selection signal. Regardless of the selection signal, power and a control signal are transmitted from the RF receiving coil driving device 24 to the RF receiving coil driving unit 63 via the power transmission line 30_4 and the control transmission line 31_4, thereby driving the RF receiving coil. Unit 63 operates. That is, the RF receiving coil driving unit 63 is always operating, and noise detection by the RF receiving coil is possible.
[0059]
Step ST5:
The operator console 15 determines whether noise is detected based on the reception signal input from the RF reception coil driving unit 63. Specifically, the operator console 15 detects noise based on the presence / absence of a noise-specific waveform peak in the received signal.
[0060]
Step ST6:
If the operator console 15 detects noise in step ST5, the process proceeds to step ST7. If no noise is detected, the operator console 15 proceeds to process in step ST8.
[0061]
Step ST7:
The operator console 15 stores information on the noise occurrence location specified by the first combination pattern selected in step ST3.
Specifically, noise generation sources in the machine room 3 and the operation room 4 are specified.
[0062]
Step ST8:
The operator console 15 determines whether or not all the predetermined first combination patterns have been selected in step ST3. If it is determined that the operator console 15 has selected, the process proceeds to step ST9 and determines that it has not been selected. If so, the process returns to step ST3.
[0063]
Step ST9:
The operator console 15 determines whether or not noise is detected in step ST6, and if detected, ends the process and displays the information on the noise occurrence location stored in step ST6 on the operation display unit 98.
The service clerk takes measures to prevent noise from being generated based on the displayed information of the noise occurrence location.
[0064]
Step ST10:
The operator console 15 outputs a selection signal instructing to supply power to all devices to the power supply device 26 via the control transmission line 27.
Further, the operator console 15 sends a control signal for instructing the switching circuits 81, 82, 83 to set all the power transmission lines and the control transmission lines to the unconnected state, and the control transmission lines 71, 72, 73. To the switching circuits 81, 82, 83.
[0065]
Step ST11:
The operator console 15 has one second combination among a plurality of second combination patterns (forms) defined in advance that indicate a combination pattern of connection and non-connection of the power transmission line and the control transmission line by the switching circuit 80. Select a pattern.
[0066]
The second combination pattern defines the connection state and non-connection state of the switching circuit 80 based on the second combination pattern, and is defined so that the location where noise occurs can be specified when noise is detected. .
For example, as the second combination pattern, the power transmission lines 30_0 and 33_0 are connected and the other transmission lines are disconnected. The control transmission lines 31_0 and 34_0 are connected and the other transmission lines are not connected. There are a pattern for setting the connection state and a pattern for setting the control transmission lines 32_0 and 35_0 to the connection state and the other to the non-connection state.
[0067]
Step ST12:
The operator console 15 outputs a selection signal for realizing the second combination pattern selected in step ST11 to the switching circuit 80 via the control transmission line 70.
The switching circuit 80 sets the corresponding power transmission line and control transmission line to a connected state or a non-connected state based on the selection signal input via the control transmission line 70.
[0068]
Step ST13:
The operator console 15 determines whether noise is detected based on the reception signal input from the RF reception coil driving unit 63.
[0069]
Step ST14:
If the operator console 15 detects noise in step ST13, the process proceeds to step ST15. If no noise is detected, the operator console 15 proceeds to process in step ST16.
[0070]
Step ST15:
The operator console 15 stores information on the noise occurrence location specified by the second combination pattern selected in step ST11.
Specifically, information indicating that any one of the power transmission lines 33_0 to 33_3 and the control transmission lines 34_0 to 34_3 and 35_0 to 35_3 is a cause of noise is stored.
[0071]
Step ST16:
The operator console 15 determines whether or not all the predetermined second combination patterns have been selected in step ST11. If it is determined that the operator console 15 has selected, the process proceeds to step ST17 and determines that it has not been selected. If so, the process returns to step ST11.
[0072]
Step ST17:
The operator console 15 determines whether or not noise is detected in step ST14, and if detected, ends the process and displays the information on the noise occurrence location stored in step ST15 on the operation display unit 98.
The service clerk takes measures to prevent noise from being generated based on the displayed information of the noise occurrence location.
[0073]
Step ST18:
The operator console 15 outputs a selection signal instructing to supply power to all devices to the power supply device 26 via the control transmission line 27.
Further, the operator console 15 sends a selection signal for instructing that the switching circuit 80 sets all the power transmission lines and the control transmission lines corresponding to the switching device 80 to the connected state via the control transmission line 70. And output to the switching circuit 80.
Thereby, the switching circuit 80 sets all the power transmission lines and control transmission lines corresponding to the switching device 80 to the connected state.
[0074]
Step ST19:
The operator console 15 is one of a plurality of third combination patterns (forms) defined in advance showing combination patterns of connection and non-connection of the power transmission line and the control transmission line by the switching circuits 81, 82, 83. A third combination pattern is selected.
[0075]
Based on the third combination pattern, the third combination pattern determines the connection state and non-connection state of the switching circuits 81, 82, and 83, and when noise is detected, makes it possible to specify the noise occurrence location. It is prescribed.
For example, as the third combination pattern, the power transmission lines 33_0 and 36_0 are connected and the other transmission lines are disconnected. The control transmission lines 34_0 and 37_0 are connected and the other transmission lines are not connected. There are a pattern for setting the connection state and a pattern for setting the control transmission lines 35_0 and 38_0 to the connection state and the other to the non-connection state.
[0076]
Step ST20:
The operator console 15 outputs a selection signal for realizing the third combination pattern selected in step ST19 to the switching circuits 81, 82, 83 via the control transmission lines 71, 72, 73.
The switching circuits 81, 82, 83 put the corresponding power transmission line and control transmission line into a connected state or a non-connected state based on selection signals input via the control transmission lines 71, 72, 73, respectively. .
[0077]
Step ST21:
The operator console 15 determines whether noise is detected based on the reception signal input from the RF reception coil driving unit 63.
[0078]
Step ST22:
If the operator console 15 detects noise in step ST21, the process proceeds to step ST23. If no noise is detected, the operator console 15 proceeds to process in step ST24.
[0079]
Step ST23:
The operator console 15 stores information on the noise occurrence location specified by the third combination pattern selected in step ST18.
Specifically, information indicating which of the power transmission lines 36_0 to 36_3 and the control transmission lines 37_0 to 37_3 and 38_0 to 38_3 is a noise generation source is stored.
[0080]
Step ST24:
The operator console 15 determines whether or not all the predetermined third combination patterns have been selected in step ST19. When it is determined that the operator console 15 has selected, the process is terminated. The process returns to step ST19.
[0081]
As described above, according to the MRI system 1, the selection signal is output from the operator console 15 to the power supply device 26 and the switching circuits 81, 82, 83 via the control transmission lines 27, 70, 71, 72, 73, respectively. By doing so, the power supply to the cradle control device 20, the display control device 21, the RF transmission coil driving device 22 and the gradient coil driving device 23, and the connection state and non-connection state of the switching circuits 80, 81, 82, 83 are arbitrarily set. Each setting can be automatically switched by the operator console 15, and the noise generation source can be automatically specified from the combination in which noise is generated in the reception result of the RF receiving coil.
Therefore, the burden on the service staff of the MRI system 1 can be reduced, the time until the noise source is specified can be shortened, and the influence on the hospital side can be reduced.
Further, since the noise generation source is automatically specified, the noise generation source can be accurately specified without depending on the skills of the service staff.
[0082]
Further, according to the MRI system 1, as shown in FIG. 5, a switching circuit 81 is provided in the cradle driving device 11, a switching circuit 82 is provided in the display device 14, and a switching circuit 83 is provided in the magnet system 12. As a result, the cradle driving device 11, the display device 14, and the magnet system 12 can be identified easily without removing the storage case.
[0083]
The present invention is not limited to the embodiment described above.
For example, in the above-described embodiment, the noise generation source is specified using the configuration illustrated in FIG. 5, but the present invention is not limited to the configuration illustrated in FIG. 5.
For example, in the present embodiment, the configuration illustrated in FIG. 5 is illustrated as an example of the present invention, but the configuration of the present invention is not limited to that illustrated in FIG.
For example, as shown in FIG. 9, a power transmission line 201 for supplying power from the power supply device 26 to the air conditioner 200 in the scan room 2 and a control transmission line 202 for sending a selection signal from the operator console 15 are provided. When specifying the noise generation source, the supply of the power and the selection signal to the air conditioner 200 may be turned on / off.
[0084]
Moreover, you may use an optical cable instead of an electric wire as the control transmission line 34_0-34_3, 35_0-35_3, 71, 72, 73, 32_4 arrange | positioned in the scan room 2 demonstrated using FIG. In this case, the switching circuits 80 and 81 only perform connection / disconnection setting of the power transmission line.
[0085]
【The invention's effect】
As described above, according to the present invention, a noise generation location specifying device that can easily specify noise that adversely affects the operation of the magnetic resonance imaging system in a short time, and a magnetic resonance image using the noise generation location specification device A system can be provided.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining an arrangement of components of an MRI system according to an embodiment of the present invention.
FIG. 2 is an external view of the magnet system and the operator console shown in FIG.
FIG. 3 is a diagram for explaining the magnet system shown in FIGS. 1 and 2;
FIG. 4 is a diagram for explaining the operator console shown in FIG. 1;
FIG. 5 is a diagram for explaining a configuration relating to specification of a noise generation location of the MRI system shown in FIG. 1;
FIG. 6 is a flowchart for explaining an operation when specifying a noise occurrence location of the MRI system 1 shown in FIG. 1;
FIG. 7 is a continuation flowchart shown in FIG. 6 for explaining an operation in specifying a noise occurrence location of the MRI system 1 shown in FIG. 1;
FIG. 8 is a continuation flowchart shown in FIG. 7 for explaining an operation in specifying a noise occurrence location of the MRI system 1 shown in FIG. 1;
FIG. 9 is a diagram for explaining a modified example of the MRI system shown in FIG. 1;
FIG. 10 is a diagram for explaining the configuration of a conventional MRI system.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... MRI system, 2 ... Scan room, 3 ... Machine room, 4 ... Operation room, 5, 8 ... Wall, 6 ... Door, 7 ... Window, 10 ... MRI apparatus, 11 ... Cradle drive device, 12 ... Magnet system, DESCRIPTION OF SYMBOLS 13 ... Subject, 14 ... Display device, 15 ... Operator console, 20 ... Cradle control device, 21 ... Display control device, 22 ... RF transmission coil drive device, 23 ... Gradient coil drive device, 26 ... Power supply device, 91a, 91b ... Magnet part, 92a, 92b ... Gradient coil part, 93a, 93b ... RF coil part, 27, 31_0 to 31_4, 32_0 to 32_4, 34_0 to 34_4, 35_0 to 35_4, 37_0 to 37_4, 38_0 to 38_4, 70, 71, 72, 73 ... transmission line for control, 28_0 to 28_5, 30_0 to 30_4, 33_0 to 33_4 36_0～36_3 ... power transmission line, 41 ... cradle drive unit, 51 ... display unit, 61 ... RF transmission coil drive section, 62 ... gradient coil driving section, 63 ... RF receiver coil driver

Claims (5)

A first room, which is a scan room, is provided with a plurality of electronic circuits, forms a high-frequency magnetic field on a subject in a static magnetic field space, and receives an electromagnetic wave generated by a spin excited from the subject by a receiving coil. A magnetic resonance imaging apparatus for obtaining a magnetic resonance signal,
Based on a first selection signal, which is disposed in a second region which is a room adjacent to the scan room, receives power and controls power and control to the corresponding electronic circuit in the magnetic resonance imaging apparatus. A plurality of signal power supply devices for determining whether to send at least one of the signals;
A power supply device disposed in the second region and configured to determine whether to supply power to the signal power supply device based on a first selection signal;
A plurality of first transmission lines for transmitting at least one of power and control signals sent from the corresponding signal power supply device;
A plurality of power and control signals that are arranged in the magnetic resonance imaging apparatus or adjacent to the magnetic resonance imaging apparatus and that are transmitted via the first transmission line are transmitted to the corresponding electronic circuit. A second transmission line of
Based on the second selection signal, it is determined whether or not to transmit at least one of the power supplied from the signal power supply device and the control signal to the first transmission line corresponding to the signal power supply device. A first switching circuit;
Whether or not to transmit at least one of the power and the control signal transmitted through the first transmission line to the second transmission line corresponding to the first transmission line based on the third selection signal A second switching circuit for determining
When the first selection signal, the second selection signal, and the third selection signal are disposed in the second region and noise is generated, the first selection signal, the second selection signal, A magnetic resonance imaging system comprising: a control device that identifies the cause of the noise based on the second selection signal, the third selection signal, and a reception result of the reception coil.   2. A third transmission line for supplying at least one of power and a control signal to the receiving coil irrespective of the first selection signal, the second selection signal, and the third selection signal. The magnetic resonance imaging system described in 1. A plurality of processing devices for performing processing used for the examination of the subject using the magnetic resonance imaging apparatus;
A plurality of processing device signal power supply devices that receive power from the power supply device and send at least one of power and a control signal to an electronic circuit in the corresponding processing device;
A plurality of processing device transmission lines that transmit at least one of power and control signals sent from the signal power supply device to an electronic circuit in the processing device;
The power sent from the processing device signal power supply device to a part or the whole of the processing device transmission line, disposed on the processing device transmission line or at the end of the processing device transmission line, and A processing device switching circuit for switching the presence or absence of supply of at least one of the control signals based on the processing device selection signal;
3. The magnetism according to claim 1, wherein the control device generates the processing device selection signal, and specifies a noise generation location based on the processing device selection signal and a detection result of the receiving coil. Resonance imaging system.   The magnetic resonance imaging system according to claim 1, further comprising an electromagnetic wave shielding member that partitions the first region and the second region. The second region has a third region that is a machine room and a fourth region that is an operation room partitioned by an electromagnetic wave shielding member,
The power supply device and the signal power supply device are disposed in the third region,
The magnetic resonance imaging system according to claim 1, wherein the control device is disposed in the fourth region.

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