JP2005211431A - Transmission circuit of ultrasonograph - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a new transmission circuit constitution of an ultrasonograph. <P>SOLUTION: This transmission circuit 12 has a waveform generating circuit 36 and a waveform selecting circuit 38. The waveform generating circuit 36 successively outputs transmission pulses corresponding to a plurality of respective vibrators 10 in response to the delay timing with respective vibrators 10, and are arranged by four in response to the respective four transmission pulses respectively different in a phase by π/2. That is, the four waveform generating circuits 36 of a waveform generating circuit 4 is arranged from a waveform generating circuit 1. The waveform selecting circuit 38 is arranged with respective vibrators 10, and outputs a driving signal corresponding to its transmission pulses by selecting the transmission pulse corresponding to the delay timing of the corresponding vibrator 10 from the transmission pulses successively outputted from the respective four waveform generating circuits 36. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a transmission circuit of an ultrasonic diagnostic apparatus that drives a plurality of transducers by electronic scanning control.

  An ultrasound diagnostic apparatus is an apparatus that acquires echo information from tissue in a subject by transmitting and receiving ultrasound to and from the subject. Electronic scanning control is known as an ultrasonic wave transmission / reception technique in an ultrasonic diagnostic apparatus. In electronic scanning control, each of a plurality of transducers is subjected to delay processing, and ultrasonic waves output from the transducers interfere with each other to form a transmission beam directed in a predetermined direction. Is done.

  When a transmission beam is formed by electronic scanning control, a drive signal subjected to delay processing corresponding to each transducer is supplied to each transducer. For this reason, a transmission circuit for generating a drive signal corresponding to each vibrator is required. In a conventional transmission circuit, a pulse generation circuit is provided for each transducer, a transmission pulse is generated for each transducer according to the delay timing of the transducer, and a drive signal corresponding to the transmission pulse is transmitted to each transducer. Has been supplied to.

  However, in the case of a two-dimensional transducer array, the number of transducers is several hundred to several thousand, and the size of the transmission circuit accompanying the large number of transducers cannot be neglected. For this reason, various techniques for suppressing an increase in the size of the transmission circuit have been proposed. For example, Patent Document 1 describes a technique for drastically reducing the wiring of an electronic circuit.

JP 2003-599 A

  While various techniques for suppressing an increase in the size of the transmission circuit have been proposed, the present invention focuses on a pulse generation circuit that generates a transmission pulse corresponding to each transducer. That is, conventionally, an attempt has been made to realize a new transmission circuit configuration by, for example, associating a pulse generation circuit provided for each transducer with a plurality of transducers.

  Accordingly, an object of the present invention is to provide a new transmission circuit configuration of an ultrasonic diagnostic apparatus.

  In order to achieve the above object, a transmission circuit of an ultrasonic diagnostic apparatus that is a preferred embodiment of the present invention is compatible with a plurality of vibrators in a transmission circuit of an ultrasonic diagnostic apparatus that supplies a drive signal to the plurality of vibrators. A signal generation unit that sequentially outputs the transmitted signal according to the delay timing of each transducer, and a signal selection unit that is provided for each transducer and outputs a drive signal to the corresponding transducer, which is sequentially output And a signal selection unit that selects a transmission signal of a corresponding transducer from the transmission signals to be output and outputs a drive signal corresponding to the transmission signal.

  According to the above configuration, since the signal generation unit outputs a transmission signal corresponding to a plurality of transducers, for example, a pulsed signal, there is no need to correspond one signal generation unit to one transducer, for example, signal generation The number of parts can be reduced from the number of vibrators.

  Preferably, a plurality of the signal generators are provided corresponding to each of a plurality of transmission signals that overlap each other on a time axis, and the signal selection unit is a transmission signal sequentially output from each of the plurality of signal generators The transmission signal of the corresponding vibrator is selected from among the above. More preferably, a plurality of the signal generators are provided corresponding to each of a plurality of transmission signals having different phases by π / n (n is a natural number).

  Preferably, the signal generation unit further includes a timing control unit that generates a timing signal for each of the signal generation units based on timing information that specifies an output timing of a transmission signal output from each of the signal generation units. The unit outputs the transmission signal based on the timing signal. More preferably, the signal selection unit further includes a selection control unit that generates a selection signal for each of the signal selection units based on selection information designating a signal generation unit selected in each of the signal selection units. Selects a transmission signal of the designated signal generation unit based on the selection signal.

  According to the present invention, a new transmission circuit configuration in a transmission circuit of an ultrasonic diagnostic apparatus is provided. As a result, for example, the transmission circuit scale is reduced.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the drawings.

  FIG. 1 shows a preferred embodiment of a transmission circuit according to the present invention, and FIG. 1 is an overall configuration diagram of an ultrasonic diagnostic apparatus using the transmission circuit according to the present invention.

  The plurality of transducers 10 are ultrasonic transducers that transmit and receive ultrasonic waves to and from the subject. The plurality of transducers 10 may constitute a one-dimensional transducer array for obtaining two-dimensional echo data, or may constitute a two-dimensional transducer array for obtaining three-dimensional echo data. In any transducer array, a drive signal is supplied from the transmission circuit 12 to each transducer 10, and electronic scanning control is executed.

  The transmission circuit 12 supplies a drive signal with an appropriate delay amount to each transducer 10 to cause the ultrasonic waves emitted from the plurality of transducers 10 to interfere with each other, thereby transmitting a directional transmission beam. To form. Each transducer 10 receives an echo from the inside of the subject with respect to this transmission beam and converts it into an electrical signal. The signals output from each transducer 10 are phased and added by the receiving circuit 14 to form a reception beam (reception signal).

  The transmission / reception control unit 16 scans the transmission beam and the reception beam by controlling the transmission circuit 12 and the reception circuit 14. For example, when a plurality of transducers 10 form a one-dimensional transducer array, the transmission beam and the reception beam are scanned two-dimensionally along a predetermined plane. Further, when the plurality of transducers 10 form a two-dimensional transducer array, the transmission beam and the reception beam are scanned three-dimensionally within a predetermined space.

  The reception signal formed by the reception circuit 14 is output to the signal processing unit 18. The signal processing unit 18 performs signal processing for the B-mode image, for example, on the received signal and outputs the signal to the image forming unit 20. The image forming unit 20 forms display image data from the signal processing result of the signal processing unit 18 and outputs the display image data to the display 22. The display 22 displays a B mode image corresponding to the display image data. Of course, the signal processing unit 18 may execute Doppler signal processing to display a Doppler waveform or a color Doppler image on the display 22. A configuration for forming a diagnostic image such as a B-mode image or a color Doppler image can be the same as a conventionally known general configuration.

  FIG. 2 is a configuration diagram of the transmission circuit 12 shown in FIG. The transmission circuit 12 includes a waveform generation circuit 36 that functions as a signal generation unit, and a waveform selection circuit 38 that functions as a signal selection unit. The waveform generation circuit 36 sequentially outputs transmission pulses corresponding to each of the plurality of transducers 10 according to the delay timing of each transducer 10, and each of the four transmission pulses having a phase difference of π / 2. There are four corresponding to these. That is, the four waveform generation circuits 36 from the waveform generation circuit (1) to the waveform generation circuit (4) are provided. The waveform selection circuit 38 is provided for each transducer 10, and selects a transmission pulse corresponding to the delay timing of the corresponding transducer 10 from the transmission pulses sequentially output from each of the four waveform generation circuits 36. A drive signal corresponding to the transmission pulse is output.

  Here, the operation principle from the generation of the transmission pulse by the waveform generation circuit 36 to the output of the drive signal by the waveform selection circuit 38 will be described with reference to FIGS. The parts shown in FIG. 2 will be described with the reference numerals in FIG.

  FIG. 3 is a diagram for explaining transmission pulses output from each of the four waveform generation circuits 36. In FIG. 3, with the horizontal axis as a time axis, the transmission pulse 40 output from the waveform generation circuit (1), the transmission pulse 42 output from the waveform generation circuit (2), and the waveform generation circuit (3) output. A transmission pulse 44 and a transmission pulse 46 output from the waveform generation circuit (4) are shown. As shown in FIG. 3, each transmission pulse is out of phase by π / 2. That is, the transmission pulse 42 is out of phase with the transmission pulse 40 by π / 2, the transmission pulse 44 is out of phase with the transmission pulse 42 by π / 2, and the transmission pulse 44 is out of phase with the transmission pulse 44. 46 is out of phase by π / 2. Thus, the four waveform generation circuits 36 can output four transmission pulses that overlap each other on the time axis. The transmission pulse in the present embodiment is not limited to the rectangular pulse shown in FIG. 3, and other waveforms may be used.

  FIG. 4 is a diagram for explaining a transmission pulse selection operation in the waveform selection circuit 38. FIG. 4A shows transmission pulses 51 to 59 corresponding to the delay timing of each transducer 10 when there are nine transducers 10. Each transmission pulse is selected by the waveform selection circuit 38 corresponding to the transducer 10. For example, the transmission pulse 51 is selected by the waveform selection circuit (1). That is, the transmission pulse 51 is selected by the waveform selection circuit (1) as the transmission pulse of the delay timing of the corresponding transducer 10 from the transmission pulses sequentially output by the four waveform generation circuits 36. Similarly, the transmission pulse 52 is selected by the waveform selection circuit (2), the transmission pulse 53 is selected by the waveform selection circuit (3), the transmission pulse 54 is selected by the waveform selection circuit (4), and the transmission pulse 55 is the waveform. The transmission circuit 56 is selected by the waveform selection circuit (6), the transmission pulse 57 is selected by the waveform selection circuit (7), and the transmission pulse 58 is selected by the waveform selection circuit (8). The transmission pulse 59 is selected by the waveform selection circuit (9).

  FIG. 4B shows transmission pulses output from each of the four waveform generation circuits 36 when the delay pattern of FIG. 4A is formed. The four waveform generation circuits 36 each output four transmission pulses having different phases by π / 2. That is, the waveform generation circuit (1) outputs the transmission pulse 61, the waveform generation circuit (2) outputs the transmission pulse 62, the waveform generation circuit (3) outputs the transmission pulse 63, and the waveform generation circuit (4). Outputs a transmission pulse 64. In this way, four transmission pulses that overlap each other on the time axis are output from different waveform generation circuits 36. The waveform generation circuit (1) also outputs a transmission pulse 65. Similarly, the transmission pulse 65 has a phase shift of 2π with respect to the transmission pulse 61 output from the waveform generation circuit (1). Therefore, the transmission pulse 61 and the transmission pulse 65 do not overlap on the time axis, and the same waveform generation circuit ( 1).

  Each waveform selection circuit 38 selects a transmission pulse corresponding to the corresponding transducer 10 from the transmission pulses 61 to 65 sequentially output from each of the four waveform generation circuits 36. That is, the waveform selection circuit (5) selects the transmission pulse 61 output from the waveform generation circuit (1) as the transmission pulse 55. The waveform selection circuit (4) selects the transmission pulse 62 output from the waveform generation circuit (2) as the transmission pulse 54, and the waveform selection circuit (6) transmits the transmission pulse 62 output from the waveform generation circuit (2). Is selected as the transmission pulse 56. Similarly, the transmission pulse 63 output from the waveform generation circuit (3) is selected as the transmission pulse 53 and the transmission pulse 57, and the transmission pulse 64 output from the waveform generation circuit (4) is the transmission pulse 52 and the transmission pulse 58. The transmission pulse 65 output from the waveform generation circuit (1) is selected as the transmission pulse 51 and the transmission pulse 59. As a result, a delay pattern from the transmission pulse 51 to the transmission pulse 59 shown in FIG. 4A is formed, and a drive signal corresponding to each transmission pulse is supplied to the corresponding transducer.

  In the transmission circuit of the present embodiment, four waveform generation circuits 36 are provided corresponding to each of four transmission pulses having phases different by π / 2. For this reason, it becomes possible to perform delay control with an accuracy of π / 2 in terms of a phase difference. For example, in FIG. 4, the transmission pulse 55 and the transmission pulse 54 are controlled with a delay time difference corresponding to the phase difference π / 2 of the transmission pulse. In the configuration of the transmission circuit of this embodiment, the accuracy of delay control can be further increased by increasing the number of waveform generation circuits 36. For example, in order to realize the delay control with the accuracy of the phase difference π / 4, it is only necessary to provide eight waveform generation circuits 36 corresponding to each of the eight transmission pulses whose phases are different by π / 4.

  Returning to FIG. 2, the operation of the transmission circuit 12 will be described in detail. In addition to the waveform generation circuit 36 and the waveform selection circuit 38, the transmission circuit 12 is provided with a counter 30, a trigger generation circuit 32 that functions as a timing control unit, and a switch control circuit 34 that functions as a selection control unit. . The transmission circuit 12 is supplied with control signals of a probe, a mode, a frequency, a beam number, a clock, and a transmission synchronization signal from a transmission / reception control unit (reference numeral 16 in FIG. 1). The clock may be output from an oscillator (not shown).

  When the transmission synchronization signal is input, the counter 30 sets the count value to “0”, performs a count-up operation at the clock cycle of the clock, and outputs the count value. The transmission synchronization signal is output for each transmission beam at the start of the transmission beam generation operation. For this reason, the count value corresponds to the time within the generation period of each transmission beam. That is, the count value is a value corresponding to time t on the horizontal axis in FIG. 4, for example. The count value output from the counter 30 is used by the trigger generation circuit 32 and the switch control circuit 34.

  FIG. 5 is a diagram for explaining the trigger generation circuit 32. The trigger generation circuit 32 outputs a timing signal indicating the output timing of the transmission pulse to each of the waveform generation circuits (1) to (4) according to the control signal. The trigger generation circuit 32 has a timing information memory 60 in which timing information 67 is recorded, and outputs a timing signal based on the timing information 67.

  The timing information 67 is a table showing on / off data for each of the four waveform generation circuits (1) to (4) corresponding to the address specified by the control signal. The count values from address 0 to 11 bits are count values output from the counter every moment. The beam numbers from address 12 bits to 19 bits are the beam numbers of the transmitted beams to be transmitted. For example, in the case of sector scanning, each beam number corresponds to the beam direction of each transmission beam, and in the case of linear scanning, each beam number corresponds to the scanning position of each transmission beam.

  The frequency from address 20 bits to 22 bits is the clock frequency. That is, it is possible to adjust the period of one count value by changing the clock frequency. The mode from address 23 bits to 25 bits indicates the operation mode of the ultrasonic diagnostic apparatus. That is, it is possible to specify data according to the operation mode (B mode, color Doppler mode, etc.) of the ultrasonic diagnostic apparatus. Probes with addresses from 26 bits to 28 bits indicate the probe type of the ultrasonic probe. For example, if the ultrasonic probe is a probe for linear electronic scanning, the mode is set to “linear”, and the probe is in accordance with the linear mode. Specified data.

  On / off data relating to each of the waveform generation circuits (1) to (4) is recorded in 3 bits of data corresponding to each address value. That is, data (1 or 0) indicating whether to output a timing signal for each waveform generation circuit is recorded. For example, when “1” is recorded in the waveform generation circuit (4) data, which is the third bit data, a timing signal is output to the waveform generation circuit (4), and the second bit data When “0” is recorded in the waveform generation circuit (3) data, the timing signal is not output to the waveform generation circuit (3). As described above, the timing information 62 is associated with the address specified by each control signal and the on / off data relating to each of the four waveform generation circuits.

  The trigger generation circuit 32 reads on / off data corresponding to an address designated by each control signal and generates a timing signal. Among the control signals, the frequency, mode, and probe are specified according to the setting state of the ultrasonic diagnostic apparatus, for example, before the transmission beam forming operation is executed. When the transmission beam forming operation is started, a beam number is designated by the transmission / reception control unit (reference numeral 16 in FIG. 1). For example, in the case of sector scanning, a beam number corresponding to the beam direction of the transmission beam is designated. When the beam number is specified, a transmission synchronization signal is output from the transmission / reception control unit, and a count value corresponding to the time within the beam generation period of the specified beam number is output from the counter every moment. The trigger generation circuit 32 reads on / off data corresponding to the count value, and outputs a timing signal corresponding to the on / off data. As a result, the trigger generation circuit 32 outputs a timing signal at a predetermined time (corresponding to the count value) in a predetermined beam direction (corresponding to the beam number). Each of the waveform generation circuits (1) to (4) outputs a transmission pulse at a timing corresponding to the timing signal output from the trigger generation circuit 32. As a result, for example, a transmission pulse is output at the timing shown in FIG.

  FIG. 6 is a diagram for explaining the switch control circuit 34. The switch control circuit 34 outputs a switch control signal to each of the waveform selection circuits (reference numeral 38 in FIG. 2) according to the control signal. Note that FIG. 6 illustrates a case where four waveform selection circuits are output, that is, a switch control signal is output to each of the waveform selection circuits (1) to (4).

  The switch control circuit 34 has a switch information memory 68 in which switch information 66 is recorded, and outputs a switch control signal based on the switch information 66.

  The switch information 66 is a table in which switch data related to each of the four waveform selection circuits (1) to (4) is shown corresponding to the address specified by the control signal. Note that the address of the switch information 66 is the same as the address of the timing information (reference numeral 62 in FIG. 5). That is, the count value from address 0 bit to 11 bit is a count value output from the counter every moment, and the beam number from address 12 bit to 19 bit is the beam number of the transmitted beam to be transmitted. The frequency from 20 bits to 22 bits is the clock frequency, and the mode from 23 bits to 25 bits indicates the operation mode of the ultrasonic diagnostic apparatus.

  In the 0 to 11 bits of data, switch data relating to each of the waveform selection circuits (1) to (4) is recorded corresponding to each address value. Data for the waveform selection circuit (1) is recorded in bits 0 to 2 of the data, data for the waveform selection circuit (2) is recorded in bits 3 to 5 of the data, and data 6 to 8 of the data is recorded. Data for the waveform selection circuit (3) is recorded in bits, and data for the waveform selection circuit (4) is recorded in bits 9 to 11 of the data. In this way, data having 3 bits is assigned to each waveform selection circuit.

  FIG. 6 shows the contents of the data for the waveform selection circuit (1). That is, 3 bits of data from 2 bits to 0 bits and the selection result are shown. For example, when the data of each bit of 2 bits, 1 bit, and 0 bit is 0, 0, 1, respectively, the output of the waveform generation circuit (1) is selected, and when the data is 0, 1, 0, the waveform generation circuit The output of (2) is selected. When the data of each bit of 2 bits, 1 bit, and 0 bit is 0, 1, 1, respectively, the output of the waveform generation circuit (3) is selected. When the data is 1, 0, 0, the waveform generation circuit is selected. The output of (4) is selected. When the data of each bit of 2 bits, 1 bit, and 0 bit is 0, 0, and 0, respectively, it is connected to the receiving circuit. Similarly to the contents of the waveform selection circuit (1) data, the waveform selection circuit data and the selection result are associated with each of the waveform selection circuits (2) to (4).

  The switch control circuit 34 reads switch data corresponding to an address specified by each control signal and generates a switch control signal. The switch control circuit 34 is supplied with the same control signal supplied to the trigger generation circuit (reference numeral 32 in FIG. 5) from the transmission / reception control section (reference numeral 16 in FIG. 1). That is, the frequency, mode, and probe are specified according to, for example, the setting state of the ultrasonic diagnostic apparatus before the transmission beam forming operation is executed. When the transmission beam forming operation is started, the beam number is designated by the transmission / reception control unit. When the beam number is specified, a transmission synchronization signal is output from the transmission / reception control unit, and the count value of the specified beam number is output from the counter every moment. The switch control circuit 34 reads switch data corresponding to the count value, and outputs a switch control signal corresponding to the switch data. Each waveform selection circuit selects a waveform generation circuit according to a switch control signal output from the switch control circuit 34.

  FIG. 7 is a diagram for explaining the waveform selection circuit. FIG. 7 shows the configuration of the waveform selection circuit 38. The waveform selection circuit 38 has a switch circuit 70, and the switch circuit 70 is provided with a buffer 72 and a switch 74 corresponding to each of the waveform generation circuits (1) to (4). Each buffer 72 is provided to ensure a voltage value, a current value, and the like of a drive signal output to the vibrator at a predetermined value. It is also possible to delete the buffer 72 when the input impedance of the vibrator is sufficiently low. Each switch 74 connects a corresponding waveform generation circuit to the vibrator. There is also a switch 74 for connecting the vibrator to the receiving circuit. The switch circuit 70 selects a switch to be connected to the vibrator based on a switch control signal output from the switch control circuit (reference numeral 34 in FIG. 6). In other words, the switch operation is executed based on the switch control signal having 3 bits supplied from the switch control circuit to each waveform selection circuit, and the selection result corresponding to the data having 3 bits of the switch control signal is obtained (see FIG. 6). In response, one of the waveform generation circuits or the reception circuit is selected. For example, when the data of each bit of 2 bits, 1 bit, and 0 bit is 0, 0, 1, respectively, the output of the waveform generation circuit (1) is selected, and when the data is 0, 1, 0, the waveform generation circuit The output of (2) is selected. A waveform selection circuit is provided for each transducer, and a transmission pulse having a delay pattern shown in FIG. 4A, for example, is selected by the selection operation of the waveform generation circuit executed for each waveform selection circuit. A drive signal corresponding to is output to each vibrator.

  As described above, in this embodiment, it is not necessary to provide a waveform generation circuit for each transducer. For this reason, the number of waveform generation circuits is reduced and the size of the transmission circuit is reduced as compared with the case where a waveform generation circuit is provided for each transducer. As the circuit scale is reduced, for example, the apparatus can be reduced in size and power can be saved. Further, as the transmission circuit scale is reduced, it becomes possible to incorporate a transmission circuit in the ultrasonic probe.

  As mentioned above, although preferred embodiment of this invention was described, embodiment mentioned above is only a mere illustration in all the points, and does not limit the scope of the present invention.

It is a figure for demonstrating embodiment of the transmission circuit which concerns on this invention. It is a block diagram of the transmission circuit which concerns on this invention. It is a figure for demonstrating the transmission pulse output from each waveform generation circuit. It is a figure for demonstrating the selection operation | movement of the transmission pulse in each waveform selection circuit. 4 is a diagram for explaining a trigger generation circuit 32. FIG. It is a figure for demonstrating a switch control circuit. It is a figure for demonstrating a waveform selection circuit.

Explanation of symbols

  10 transducer, 12 transmission circuit, 30 counter, 32 trigger generation circuit, 34 switch control circuit, 36 waveform generation circuit, 38 waveform selection circuit.

Claims (5)

In a transmission circuit of an ultrasonic diagnostic apparatus that supplies drive signals to a plurality of transducers,
A signal generator that sequentially outputs transmission signals corresponding to a plurality of transducers according to the delay timing of each transducer;
A signal selection unit that is provided for each transducer and outputs a drive signal to the corresponding transducer, and selects a transmission signal of the corresponding transducer from the sequentially output transmission signals, and uses the transmission signal as the transmission signal. A signal selection unit that outputs a corresponding drive signal;
Having
A transmission circuit for an ultrasonic diagnostic apparatus. The transmission circuit according to claim 1,
A plurality of the signal generators are provided corresponding to each of a plurality of transmission signals overlapping each other on the time axis,
The signal selection unit selects a transmission signal of a corresponding transducer from transmission signals sequentially output from each of the plurality of signal generation units;
A transmission circuit for an ultrasonic diagnostic apparatus. The transmission circuit according to claim 2,
A plurality of the signal generation units are provided corresponding to each of a plurality of transmission signals having different phases by π / n (n is a natural number),
A transmission circuit for an ultrasonic diagnostic apparatus. The transmission circuit according to claim 2 or 3,
A timing controller that generates a timing signal for each of the signal generators based on timing information that specifies an output timing of a transmission signal output from each of the signal generators;
Further comprising
Each of the signal generators outputs the transmission signal based on the timing signal.
A transmission circuit for an ultrasonic diagnostic apparatus. The transmission circuit according to any one of claims 2 to 4,
A selection control unit that generates a selection signal for each of the signal selection units based on selection information that specifies a signal generation unit to be selected in each of the signal selection units;
Further comprising
Each signal selection unit selects a transmission signal of the designated signal generation unit based on the selection signal,
A transmission circuit for an ultrasonic diagnostic apparatus.

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