JP2004073620A - Ultrasonic diagnostic device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To display a higher harmonic wave ultrasonic image of an excellent S/N without complicating a device when extracting and imaging a higher harmonic wave component from an ultrasonic signal received from the inside of an examinee body. <P>SOLUTION: The ultrasonic diagnostic device is provided with: an ultrasonic probe 1 equipped with a plurality of ultrasonic vibrators; a means 2 for transmitting the ultrasonic wave of a first frequency; a means 3 for receiving the ultrasonic wave of the first frequency and the ultrasonic wave of a second frequency which is a higher harmonic wave component of the ultrasonic wave by using a plurality of channels; means 4 and 5 for generating image data from the ultrasonic waves of the first frequency and the second frequency; and a means 8 for displaying the image data generated by the image generating means, and the ultrasonic vibrator is connected in parallel to a prescribed channel in the receiving means for the first frequency and a prescribed channel in the receiving means for the second frequency. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an ultrasonic diagnostic apparatus, and more particularly, to an ultrasonic diagnostic apparatus that improves S / N of an image using a harmonic component of a received signal.
[0002]
[Prior art]
An ultrasonic diagnostic system emits ultrasonic waves generated from an ultrasonic transducer incorporated in an ultrasonic probe into a subject, and receives a reflected signal generated by a difference in acoustic impedance of a subject tissue by the ultrasonic transducer. Is displayed on the monitor.
[0003]
Since this diagnostic method can easily observe a real-time two-dimensional image with a simple operation just by bringing the ultrasonic probe into contact with the body surface, it is widely used for functional examination of the heart and the like and morphological diagnosis of various organs. Since there is almost no irradiation damage to the specimen, it has become an indispensable diagnostic imaging method for fetal growth diagnosis.
[0004]
Conventionally, in an ultrasonic diagnostic method, an optimal ultrasonic frequency is selected for a diagnostic site, an ultrasonic pulse having this frequency as a center frequency is radiated into the subject, and a reflected ultrasonic wave from the subject which is almost equal to this frequency is used. I have been receiving sound waves for imaging.
[0005]
On the other hand, in recent years, a new imaging technique called tissue harmonic imaging (hereinafter, referred to as THI) has been developed and has begun to spread widely in clinical settings. This imaging method is an imaging method that effectively utilizes an ultrasonic nonlinear phenomenon occurring in a subject tissue. For example, when an ultrasonic pulse having a center frequency of fo is radiated into the subject, a non-linear A double harmonic component (2fo) is newly generated due to the phenomenon, and the harmonic component is received by the ultrasonic probe together with the fundamental component (fo). The generation of this harmonic component depends on the properties of the tissue of the subject, the propagation distance to the reflection site, or the ultrasonic intensity at the reflection site, and in particular, the dependence of the ultrasonic intensity is a cause of artifacts in conventional ultrasonic images. Since the occurrence of the side lobe can be suppressed, a clear image can be obtained by an imaging method using this harmonic component, that is, THI.
[0006]
[Problems to be solved by the invention]
However, since the power of the harmonic component obtained from the inside of the subject is generally smaller than the fundamental component by about 20 dB, the THI reduces the harmonic component of the ultrasonic reception signal under good S / N conditions. Is very important.
[0007]
On the other hand, as described above, the received signal from the subject contains a fundamental component and a harmonic component mixedly, and the harmonic component to be used as THI is 1/10 or less of the fundamental component. is there. Therefore, if the dynamic range of the receiving circuit is not sufficiently wide, the dynamic range of the harmonic component becomes small, and an image having a sufficient S / N cannot be obtained.
[0008]
In particular, in recent ultrasonic diagnostic apparatuses, digitization of a receiving circuit has progressed, and a configuration is adopted in which received signals from a plurality of transducers are converted into digital signals before performing beamforming. In this case, the received signal including the fundamental wave component is assigned to the input range of the A / D converter, and therefore, the dynamic range for harmonic components required for image generation is greatly reduced. For example, when a 10-bit A / D converter is used, a dynamic range of about 60 dB can be secured for a fundamental component, but a dynamic range for a harmonic component that is 20 dB lower than the fundamental component is 40 dB. A small signal of / 100 or less is buried in quantization noise generated at the time of A / D conversion. That is, when the receiving circuit is configured by a circuit having a limited dynamic range, such as an A / D converter, a harmonic image excellent in S / N due to a fundamental component mixed in the received signal. Is difficult to obtain.
[0009]
The present invention has been made to solve such a conventional problem, and an object thereof is to generate an ultrasonic image from a harmonic component of a reception signal obtained by an ultrasonic transducer. It is an object of the present invention to provide an ultrasonic diagnostic apparatus capable of significantly improving S / N as compared with the conventional method.
[0010]
[Means for Solving the Problems]
In order to solve the above problems, an ultrasonic diagnostic apparatus according to the present invention includes an ultrasonic probe including a plurality of ultrasonic transducers, and an ultrasonic pulse having a first center frequency by driving the ultrasonic transducer. And a harmonic component extraction unit for extracting, from an ultrasonic signal received by the ultrasonic transducer, a reception signal having a frequency that is substantially an integral multiple of the first center frequency. First ultrasonic receiving means having a plurality of receiving channels having means, and a receiving signal having a frequency component at least substantially equal to the first center frequency from an ultrasonic signal received by the ultrasonic transducer. A second ultrasonic receiving unit having a plurality of receiving channels for receiving, a first image data generating unit for generating image data for a received signal obtained by the first receiving unit; Second image data generating means for generating image data for a received signal obtained by the second receiving means; first image data generated by the first image generating means; and the second image Display means for displaying at least one of the second image data generated by the generation means, and at least one of the ultrasonic transducers of the ultrasonic probe being received by the first ultrasonic reception means in a predetermined manner. A channel and a predetermined receiving channel of the second ultrasonic receiving means are connected in parallel.
[0011]
Therefore, according to the present invention, it is possible to obtain an ultrasonic image having a good S / N from a harmonic component included in a received signal without complicating the configuration of the device.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0013]
(First Embodiment)
A feature of the present embodiment is that, when the number of channels in the receiving unit of the ultrasonic diagnostic apparatus is larger than the number of channels in the ultrasonic probe, that is, the number of ultrasonic transducers, a plurality of receiving circuits are provided in one ultrasonic vibration element. By connecting a filter circuit at the first stage of the receiving circuit, a fundamental wave component and a harmonic component of a received wave from the subject are received with good S / N.
[0014]
Generally, the number of transducers of the ultrasonic probe 1 used in the ultrasonic diagnostic apparatus differs depending on the type of the probe. In the following, the number of transducers of the sector scanning probe is N, the number of transducers of the convex scanning probe is 2N (N = 256), and the convex scanning probe is an ultrasonic probe connectable to the ultrasonic diagnostic apparatus. The case where the maximum number of transducers is used will be described as an example.
[0015]
In this case, the number of channels in the ultrasonic transmitting unit 2 and the ultrasonic receiving unit 3 of the ultrasonic diagnostic apparatus is provided corresponding to the maximum number of transducers 2N of the ultrasonic probe connected to this unit. In the present embodiment, an ultrasonic probe having a transducer number of about 1/2, such as a sector scanning probe, is connected to an apparatus having a transmission / reception circuit having 2N channels as described above. A THI image excellent in N is generated.
[0016]
1 to 5, a first embodiment of the present invention will be described. First, the device configuration of the first embodiment will be described with reference to FIGS. 1 is a block diagram showing a schematic configuration of the entire apparatus, and FIG. 2 is a block diagram showing a detailed configuration of the ultrasonic receiving unit 3. In FIG. 2, the number of transducers (N) is set to 4 and the number of reception channels (2N) is set to 8 for reasons of space.
[0017]
The ultrasonic diagnostic apparatus includes an ultrasonic probe 1 that transmits and receives ultrasonic waves by contacting the surface of a subject, and an ultrasonic diagnostic apparatus main body 50 that generates an image based on a signal obtained from the ultrasonic probe 1. The ultrasonic diagnostic apparatus main body 50 includes an ultrasonic transmitter 2 that generates a drive signal for generating an ultrasonic wave, an ultrasonic receiver 3 that receives an ultrasonic reflected signal from the inside of the subject, A B-mode processing unit 4 for performing signal processing for generating B-mode image data using the same and a Doppler mode processing unit 5 for performing signal processing for generating color Doppler image data are provided.
[0018]
Further, the ultrasonic diagnostic apparatus main body 50 includes an image display unit 8 that stores various types of obtained image data and converts the data into a TV format, an input unit 7, and a system control unit 6 that controls these units in a comprehensive manner. ing.
[0019]
The ultrasonic probe 1 is a dedicated probe wired for harmonic imaging, has a plurality of (N) ultrasonic transducers 28 arranged one-dimensionally at a distal end portion, and has a distal end with respect to a subject. The parts are brought into contact to transmit and receive ultrasonic waves. Each of the ultrasonic transducers 28 is connected to two terminals of a connector 31, and is connected to the ultrasonic transmitting unit 2 and the ultrasonic receiving unit 3 of the ultrasonic diagnostic apparatus main body 50 via the connector 31. . The ultrasonic transducer 28 is an electroacoustic transducer, and has a function of converting an electric pulse into an ultrasonic pulse at the time of transmission, and a function of converting an ultrasonic signal into an electric signal at the time of reception.
[0020]
The ultrasonic probe 1 is arbitrarily selected from among those corresponding to a sector scan, those corresponding to a linear scan, those corresponding to a convex scan, and the like in accordance with the diagnostic site. The case of using is described.
[0021]
The ultrasonic transmission unit 2 includes a rate pulse generator 11, a transmission delay circuit 12, and a pulser 13. The rate pulse generator 11 generates a rate pulse for determining a repetition period of an ultrasonic pulse radiated into the subject. The transmission delay circuit 12 is a delay circuit for determining a convergence distance and a deflection angle of an ultrasonic beam during transmission, and determines timing for driving a plurality of ultrasonic transducers. The pulser 13 is a drive circuit that generates a high-voltage pulse for driving the ultrasonic transducer.
[0022]
The rate pulse generator 11 supplies a rate pulse for determining a repetition period of the ultrasonic pulse radiated into the subject to the transmission delay circuit 12. The transmission delay circuit 12 is composed of an independent delay circuit twice as large as the ultrasonic transducer used for transmission (2N), and converges ultrasonic waves to a predetermined depth in order to obtain a narrow beam width in transmission. A delay time for transmitting the ultrasonic wave in a predetermined direction and a delay time for transmitting the ultrasonic wave in a predetermined direction are supplied to the pulser 13.
[0023]
The pulsar 13 has the same number of 2N independent driving circuits as the transmission delay circuit 12, and drives the ultrasonic vibrator 28 built in the ultrasonic probe 1 to emit ultrasonic waves into the subject. Is formed.
[0024]
The ultrasonic receiver 3 includes a band pass filter (BPF) 14, a preamplifier 15, an A / D converter 16, and a phasing adder 17. The BPF 14 includes a BPF 14-1 for extracting a harmonic component of a received signal and a BPF 14-2 for extracting a fundamental wave component. The preamplifier 15-1 is provided for each of the two types of BPFs 14-1 and 14-2. , 15-2, A / D converters 16-1, 16-2, and phasing adders 17-1, 17-2. The preamplifier 15 is designed to amplify a small signal converted into an electric signal by the ultrasonic vibrator and secure a sufficient S / N, and the maximum output amplitude of the received signal at the output terminal of the preamplifier 15 is A The amplification degree is controlled by the system control circuit so as to correspond to the input dynamic range of the / D converter 16. This includes gain correction according to the respective signal amplitudes lost due to the insertion of the BPF 14-1 and the BPF 14-2. The fundamental component and the harmonic component of the received signal amplified to a predetermined size in the preamplifier 15 are converted into digital signals by an A / D converter 16 and sent to a phasing adder 17.
[0025]
The phasing adder 17 includes a beamformer 29 and an adder 30 as shown in FIG. 2, and the beamformer 29 converges ultrasonic waves from a predetermined depth to obtain a narrow reception beam width. The convergence delay time and the reception directivity of the ultrasonic beam are sequentially changed, and a delay time for scanning the inside of the subject is given to the reception signal converted into a digital signal. Add the outputs.
[0026]
The B-mode processing unit 4 includes a logarithmic converter 18 and an envelope detector 19. The logarithmic converter 18 includes a look-up table that logarithmically converts an input value and outputs the result. The digital input signal of the B-mode processing unit 4 performs logarithmic conversion of the amplitude of a received signal in the logarithmic converter 18 to convert a weak signal. Emphasize relatively. Generally, a received signal from the inside of a subject has an amplitude having a wide dynamic range of 80 dB or more. In order to display this on a normal television monitor having a dynamic range of about 30 dB, an amplitude that emphasizes a weak signal is used. Compression is required. The envelope detector 19 performs an envelope detection operation on the logarithmically converted digital signal to detect an amplitude envelope.
[0027]
The Doppler mode processing unit 5 includes a quadrature detection circuit 20, a Doppler signal storage circuit 21, an FFT analyzer 22, and a calculator 23. The Doppler mode processing unit 5 mainly performs FFT analysis and various calculations on the Doppler component of the received signal.
[0028]
That is, the input signal of the Doppler mode processing unit 5 is converted into a complex signal in the quadrature detection circuit 20, and the FFT analyzer 22 temporarily stores the mutually orthogonal complex components in the Doppler signal storage circuit 21, Perform FFT analysis. On the other hand, the arithmetic unit 23 calculates the center and spread of the spectrum obtained by the FFT analyzer 22.
[0029]
The image display section 8 includes a display image memory 25, a display circuit 26, and a monitor 27. The display image memory 25 temporarily stores image data such as a B-mode image and a color Doppler image displayed on the monitor 27 and character and numeric data accompanying the image data. The image data stored in the display image memory 25 is read out according to an instruction from the system control unit 6, D / A-converted by the display circuit 26, converted into a television format, and displayed on the monitor 27.
[0030]
The system control unit 6 controls each unit such as the ultrasonic transmission unit 2, the ultrasonic reception unit 3, and the image display unit 8 and controls the entire system based on an instruction signal from the input unit 7. In particular, in the present embodiment, the control signal for determining the filter characteristics such as the center frequency and the frequency band in the BPF 14 and the control of the changeover switch 32 for bypassing the BPF 14 are sent to the ultrasonic receiving unit 3. At this time, the rate pulse of a predetermined channel sent from the rate pulse generator 11 is stopped in order to stop driving of a part of the pulser 13.
[0031]
The input unit 7 includes a keyboard, a trackball, a mouse, and the like on an operation panel, and is used by an apparatus operator to input patient information, imaging conditions of the apparatus, and image quality conditions. Further, an execution command of the present embodiment is input.
[0032]
A transmission circuit is connected to each of the two reception circuits commonly connected to each of the ultrasonic transducers 28. In the present embodiment, by controlling the supply of the rate pulse, any one of the transmission circuits is connected. One of the transmission circuits drives the ultrasonic transducer 28, and FIG. 2 shows only the pulsar 13 of the transmission circuit that contributes to the driving.
[0033]
Next, a procedure of image data collection in the first embodiment will be described with reference to FIGS. FIG. 3 is a flowchart showing a procedure for collecting image data in the present embodiment.
[0034]
The operator connects the ultrasonic probe 1 dedicated to THI having the above-described configuration to the ultrasonic diagnostic apparatus main body 50 (step S1), and uses the input unit 7 to execute the present embodiment in an imaging mode (hereinafter, referred to as an S / N improvement mode). Is selected (step S2). The system control unit 6 receives a command signal of the S / N improvement mode from the input unit 7, and further reads probe ID information from the ultrasonic probe 1. Next, the system control unit 6 reads related information such as the ultrasonic frequency of the ultrasonic probe 1 stored in advance in a storage circuit (not shown) in the system control circuit 6 based on the probe ID information, Based on these related information, the filter characteristics such as the center frequency and band of the BPFs 14-1 and 14-2, and further, the attenuation in the stop band are set (step S3).
[0035]
Specifically, the BPF 14 is configured by a varicap diode or the like, and electronically controls the filter characteristics by controlling the voltage applied to the varicap diode. When the resonance frequency of the ultrasonic transducer 28 constituting the ultrasonic probe 1 is fo, the center frequency of the BPF 14-1 is set to 2fo and the center frequency of the BPF 14-2 is set to fo by electronic control. . In the case other than the S / N improvement mode, the BPFs 14-1 and 14-2 are controlled to be bypassed by an electronic switch (not shown).
[0036]
When the setting of the S / N improvement mode is completed, a scanning start command of the S / N improvement mode is sent from the input unit 7 to the system control unit 6 by the operator, and transmission and reception of the ultrasonic wave are started (step S4). .
[0037]
Upon transmission of the ultrasonic wave, the rate pulse generator 11 supplies a rate pulse for determining a repetition period of the ultrasonic pulse radiated into the subject to the transmission delay circuit 12 according to a control signal from the system control unit 6. The transmission delay circuit 12 controls a delay time for converging an ultrasonic wave to a predetermined depth to obtain a narrow beam width in transmission and a delay time for transmitting an ultrasonic wave in a predetermined direction (θ1). The pulse is supplied to the pulser 13.
[0038]
The pulser 13 drives the ultrasonic transducer 28 incorporated in the ultrasonic probe 1 by an ultrasonic transducer driving pulse generated by driving the rate pulse, and emits an ultrasonic pulse having a center frequency fo into the subject. . The transmission delay circuit 12 and the pulser 13 are composed of 2N channels, and all the channels are independently connected to the respective ultrasonic transducers 28 via the connectors 31 except in the S / N improvement mode. You.
[0039]
On the other hand, in the present embodiment, since the two pulsar output lines are also commonly connected by the ultrasonic probe 1, only one of the two pulsars 13 is used by using any one of the two pulsars 13. The vibrator is driven. 2, pulsars 13-1 to 13-4 used for driving the vibrator are selected by a control signal of the system control unit 6, and the ultrasonic vibrator 28-1 is driven by driving pulses of these pulsars 13-1 to 13-4. Are driven to emit ultrasonic waves into the subject.
[0040]
However, the vibrators 28-1 to 28-4 connected to the output terminals of the pulsars 13-1 to 13-4, the BPFs 14-1-1 to 4-1-4, and the BPFs 14-2-1 to 4-1 to be described later. If there is a margin in the withstand voltage characteristics in 14-2-4, it is possible to drive the vibrator by simultaneously using other commonly connected pulsars 13 (not shown). In this case, an equal delay time is given by the transmission delay circuit 12 to the rate pulses for driving these two commonly connected pulsers 13.
[0041]
A part of the ultrasonic wave radiated into the subject is reflected on a boundary surface between organs in the subject having different acoustic impedances or on a tissue. When this ultrasonic wave is reflected by a moving reflector such as a heart wall or a blood cell, the ultrasonic frequency undergoes a Doppler shift. Further, due to the non-linear characteristics of the subject tissue, these ultrasonic waves newly generate an ultrasonic pulse having a center frequency of 2fo. Therefore, the ultrasonic wave reflected in the subject tissue and returned to the ultrasonic probe 1 includes an ultrasonic pulse (a fundamental wave component) having a center frequency fo at the time of transmission and an ultrasonic pulse (a harmonic component) having a center frequency of 2fo. ) Are mixed.
[0042]
FIG. 4 shows a frequency spectrum of the ultrasonic signal received at this time. FIG. 4A shows a frequency spectrum of an ultrasonic pulse transmitted into the subject, which is distributed around fo. On the other hand, the frequency spectrum of the reflected signal from the subject shown in FIG. 4B is composed of a fundamental component distributed around fo and a harmonic component distributed around 2fo. Generally, the harmonic component is about 20 dB smaller than the fundamental component. Incidentally, the cause of the generation of the harmonic is that the propagation speed of the ultrasonic pulse in the tissue of the subject depends on the sound pressure of the ultrasonic wave. Is known to occur.
[0043]
In addition, by obtaining an ultrasonic image using only these harmonic components, it is possible to suppress a side lobe, which has been a main cause of an artifact that has conventionally occurred on an image, so that a good image can be obtained. As already described, this harmonic component imaging technique has been spotlighted in recent years as harmonic imaging.
[0044]
The received signal from the inside of the subject is received by the same ultrasonic vibrator 28 as at the time of transmission, and is converted from an ultrasonic wave into an electric signal. As for the received signal converted into the electric signal, a received signal of a predetermined band is selected in the BPF 14 of the ultrasonic receiving unit 3, and the selected received signal component is amplified to a predetermined size by the preamplifier 15. The digital signal is converted by the A / D converter 16. Further, the reception signal converted into the digital signal is given a predetermined delay time by the beamformer 29 of the phasing adder 17 based on the control signal from the system control unit 6, and then added and synthesized by the adder 30. You.
[0045]
The configuration and function of the ultrasonic receiving unit 3 will be described in more detail with reference to FIG. In FIG. 2, a reception signal from the ultrasonic probe 1 including four ultrasonic transducers 28-1 to 28-4 is supplied to the ultrasonic receiving unit 3 including an eight-channel receiving circuit. In this case, two receiving circuits are commonly connected to one ultrasonic transducer 28. That is, the reception signal from the transducer 28-1 is supplied to the BPF 14-1-1 and the BPF 14-2-1, and the reception signal from the transducer 28-2 is supplied to the BPF 14-1-2 and the BPF 14-2-2. Supplied to Similarly, the reception signal from the transducer 28-3 is supplied to the BPF 14-3 and the BPF 14-2-3, and the reception signal from the transducer 28-4 is supplied to the BPF 14-1-4 and the BPF 14-2-4. Supplied to
[0046]
In this case, the BPF 14-1-1, the BPF 14-1-2, the BPF 14-1-3, and the BPF 14-1-4 are for extracting the harmonic component of the center frequency 2fo from the received signal components shown in FIG. It is a bandpass filter. On the other hand, the BPF 14-2-1, the BPF 14-2-2, the BPF 14-2-3, and the BPF 14-2-4 are band-pass filters for extracting a fundamental component of the center frequency fo.
[0047]
The harmonic component of the received signal extracted by the BPF 14-1-1 is amplified to a predetermined size by the preamplifier 15-1-1 and then converted to a digital signal by the A / D converter 16-1-1. Is done. At this time, the amplification degree of the preamplifier 15-1-1 is set in advance so that the maximum amplitude of the output signal of the BPF 14-1-1 corresponds to the input dynamic range of the A / D converter 16-1-1. .
[0048]
The A / D-converted reception signal is supplied to an adder 30-1 after a predetermined delay time is given by a beamformer 29-1-1. The beamformer 29-1-1 has a delay time for converging an ultrasonic wave from a predetermined depth to obtain a narrow beam width in reception, and a strong reception directivity in a predetermined direction with respect to the ultrasonic beam. This is a variable delay circuit for giving a delay time to a received signal with a delay, and the delay time is set by control data from the system control unit 6, and the reception directivity is first set in the θ1 direction. (Step S5).
[0049]
On the other hand, the output signal of the BPF 14-2-1 obtained by extracting only the fundamental wave component from the received signal obtained from the same oscillator 28-1 is amplified to a predetermined size by the preamplifier 15-2-1. , Are converted into digital signals by an A / D converter 16-2-1 and further given a predetermined delay time by a beamformer 29-2-1, and then supplied to an adder 30-2. Also in this case, the amplification degree of the preamplifier 15-2-1 is preset so that the maximum amplitude of the output signal of the BPF 14-2-1 corresponds to the input dynamic range of the A / D converter 16-1-1. . As shown in FIG. 4, this fundamental wave component is generally about 20 dB larger than the harmonic component, so that the amplification of the preamplifier 15-2-1 is about 20 dB lower than the amplification of the preamplifier 15-1-1. Note that the delay time given to the received signal in the beamformer 29-2-1 is equal to that in the case of the beamformer 29-1-1.
[0050]
Similarly, received signals from the vibrators 28-2 to 28-4 have BPFs 14-1-2 to 14-1-4 having band-pass characteristics of a center frequency 2fo and band-pass characteristics of a center frequency fo, respectively. BPF14-2-2 to BPF14-2-4 are supplied to two systems, and the outputs of BPF14-1-2 to BPF14-1-4 are output from preamplifiers 15-1-2 to 15-1-4, A / D The signals are sent to the adder 30-1 via the converters 16-1-2 to 16-1-4 and the beamformers 29-1-2 to 29-1-4. On the other hand, the outputs of the BPFs 14-2-2 to 14-2-4 are output from the preamplifiers 15-2-2 to 15-2-4, the A / D converters 16-2-2 to 16-2-4, and the beam former 29. -2-2 to 29-2-4 are sent to the adder 30-2.
[0051]
In the adder 30-1, harmonic components are added and synthesized from the received signals received by the transducers 28-1 to 28-4, and a harmonic received signal having reception directivity in the θ1 direction is formed. On the other hand, the adder 30-2 adds and synthesizes the fundamental wave components to form a fundamental wave reception signal having reception directivity in the θ1 direction (step S6).
[0052]
Several methods can be considered for image formation using the harmonic component and the fundamental component obtained by such a procedure, but in the present embodiment, a B-mode image (a so-called THI image) based on the harmonic component is used. And the display of the color Doppler image by the fundamental wave component will be described below.
[0053]
That is, the harmonic reception signal of the adder 30-1 is sent to the B-mode processing unit 4, and the fundamental wave reception signal of the adder 30-2 is sent to the Doppler mode processing unit 5. The output of the adder 30-1 sent to the B-mode processing unit 4 is subjected to logarithmic conversion and envelope detection in a logarithmic converter 18 and an envelope detector 19, and then the display image memory 25 of the image display unit 8. (Step S7).
[0054]
On the other hand, in the generation of a color Doppler image, in order to obtain the Doppler shift of the ultrasonic reception signal, the system control unit 6 continuously transmits and receives ultrasonic waves in the same direction (θ1) a plurality of times. An FFT (Fast-Fourier-Transform) analysis is performed on the obtained received signal.
[0055]
That is, the ultrasonic wave transmission / reception is performed a plurality of times in the θ1 direction. At this time, the quadrature detection circuit 20 of the Doppler mode processing unit 5 performs quadrature phase detection on the respective fundamental wave reception signals obtained from the adder 30-2. To convert the signal into a complex signal having a real part and an imaginary part, and sequentially store the complex signal in the Doppler signal storage circuit 21. Next, the FFT analyzer 22 obtains the frequency spectrum of the Doppler signal using the plurality of fundamental wave reception signals stored in the Doppler signal storage circuit 21. Further, the arithmetic unit 23 calculates the center (average velocity of blood flow) and the variance (state of turbulence of blood flow) with respect to the frequency spectrum output from the FFT analyzer 22, and the system control unit 6 The result is read and stored together with the THI image data in the storage area corresponding to θ1 of the display image memory 25 (step S8).
[0056]
When the collection and storage of the THI image data and the color Doppler image data in the θ1 direction are completed, the transmission / reception direction of the ultrasonic wave is changed to θ1 + (m−1) Δθ (m = 2 to M) while being sequentially updated by Δθ. Ultrasonic waves are transmitted and received in the same procedure as above by scanning M lines, and the inside of the subject is scanned. At this time, the system control unit 6 collects each of the THI image data and the color Doppler image data while sequentially switching the delay times of the transmission delay circuit 12 and the beamformer 29 in accordance with the ultrasonic transmission / reception direction by the control signal. (Step S9).
[0057]
The system control unit 6 can store the THI image and the color Doppler image in independent image memories in the display image memory 25, and can also combine and store these two types of images. When the generation of one THI image, color Doppler image, or a composite image thereof is completed in the display image memory 25, the system control unit 6 converts the image data selected according to the instruction signal from the input unit 7. The data is read from the display image memory 25 and displayed on the monitor 27 via the display circuit 26 (step S10).
[0058]
Next, S / N improvement of a THI image in the present embodiment will be described with reference to FIG.
[0059]
FIG. 5A shows the S / N of the harmonic component when the received signal is input to the 10-bit A / D converter 16 without passing through the BPF 14-1, and the quantization noise level is A. The noise level is determined by the LSB of the / D converter 16. In this case, as described above, the input dynamic range of 60 dB of the 10-bit A / D converter 16 is almost allotted by a fundamental component that is 20 dB larger than the harmonic component, and the component assigned to the harmonic component is 40 dB.
[0060]
On the other hand, an input dynamic range of 60 dB is allocated to the harmonic component by eliminating the fundamental component using the BPF 14-1 having the band-pass characteristic as shown in FIG. 5B. That is, according to this embodiment, the S / N of the harmonic component can be improved by 20 dB. Incidentally, in the conventional THI image generation, after the received signals of the respective channels are combined in the adder 30, filtering for removing the fundamental wave component has been performed. For this reason, the A / D converter 16 has a problem as shown in FIG. 5A because a received signal in which a fundamental wave and a harmonic are combined is input.
[0061]
Next, a first modification of the present embodiment will be described with reference to FIG. In the first embodiment shown in FIG. 2, the common connection of the signal line for supplying the reception signal from the ultrasonic transducer 28 to the two-channel receiving circuit is performed in the ultrasonic probe 1. According to the method, the configuration of the ultrasonic probe 1 becomes special, and it is necessary to provide the ultrasonic probe 1 for exclusive use.
[0062]
On the other hand, according to this modification, even when the general-purpose ultrasonic probe 1 is connected, the same effect as that of the first embodiment can be obtained. That is, the changeover switch 32 is provided in a stage preceding the BPF 14 of the ultrasonic receiving unit 3, and the input terminal of the BPF 14-1-1 and the input terminal of the BPF 14-2-1 are connected via the changeover switch 32-1. , BPF 14-1-2 and BPF 14-2-2 are also connected via the changeover switch 32-2. Similarly, BPF 14-1-3 and BPF 14-2-3 are connected via a changeover switch 32-3, and BPF14-1-4 and BPF14-2-4 are connected via a changeover switch 32-4.
[0063]
In this case, when the operator connects the ultrasonic probe 1 to the ultrasonic diagnostic apparatus main body 50 and selects the S / N improvement mode in the input unit 7, the system control unit 6 sends a command for the S / N improvement mode from the input unit 7. Upon receiving the signal, probe ID information is read from the ultrasonic probe 1. Further, the system control unit 6 reads related information such as the ultrasonic frequency of the probe stored in advance in a storage circuit (not shown) in the system control circuit 6 based on the probe ID. The center frequency and band of -1 and 14-2, as well as the amount of attenuation in the stop band, and the like are set. Further, the system control unit 6 sends a control signal to the changeover switch 32, and outputs the BPFs 14-1-1 and 14-2-1, the BPFs 14-1-2 and 14-2-2, and the BPFs 14-1-3 and 14-2. -3, and the input terminals of the BPFs 14-1-4 and 14-2-4 are connected by change-over switches 32-1 to 32-4.
[0064]
As described above, the changeover switches 32-1 to 32-4 are newly installed inside the ultrasonic diagnostic apparatus main body 50, and the changeover switches 32-1 to 32-4 are set based on the selection command of the S / N improvement mode. By performing the control, a general-purpose probe can be used as the ultrasonic probe 1 connected to the ultrasonic diagnostic apparatus main body 50. The changeover switch 32 used in this modification may be an electronic switch, but is preferably a mechanical changeover switch such as a relay switch that does not generate noise.
[0065]
In the above modification, the addition result of the outputs of the BPFs 14-2-1 to 14-2-4 is sent to the Doppler mode processing unit 5, and the addition result of the outputs of the BPFs 14-1-1 to 14-1-4 is sent to the BPF 14-1. Although the configuration is such that the output to the mode processing unit 4 is provided, the output of the BPF 14-2-1 to BPF 14-2-4 and the output of the BPF 14-1-1 to BPF 14-1-4 are all added to generate a wideband signal. Then, the signal may be sent to the B-mode processing unit 4 or the Doppler mode processing unit 5 to generate an ultrasonic image. Further, the signal to be sent to the B-mode processing unit 4 and the Doppler mode processing unit 5 may be arbitrarily switched from a signal of a fundamental component, a signal of a harmonic component, and a wideband signal.
[0066]
Next, a second modification of the present embodiment will be described with reference to FIG. FIG. 7A shows an ultrasonic wave corresponding to a two-dimensional array ultrasonic probe 51 configured by arranging the ultrasonic transducers 2N in the scanning direction (x direction) by 2N and in the slice direction (y direction) by three or two dimensions. This is a case where the present embodiment is applied to the receiving unit 3. However, in this figure, the number of transducers in the scanning direction is set to 4 (N = 2) due to space limitations.
[0067]
The purpose of using the two-dimensional array ultrasonic probe 51 is to improve the beam width in the slice direction and to perform three-dimensional ultrasonic scanning. For the former, Japanese Patent Application Laid-Open No. 9-526 discloses a method of improving the beam width in the slice direction without increasing the number of channels of the reception circuit by receiving reception signals from transducers arranged in the slice direction in time series. A method is described. On the other hand, for the latter, JP-A-11-222217 discloses a three-dimensional scanning method capable of real-time display by applying a parallel simultaneous reception method and a gate scanning method for extracting a signal from a specific depth. Have been. These publications describe a method of activating a two-dimensional array probe according to each purpose, and a description thereof will be omitted.
[0068]
FIG. 7B shows a case where the ultrasonic probe 1 in which 2N ultrasonic transducers 28 are arranged one-dimensionally in the scanning direction (x direction) is connected to the ultrasonic receiving unit 3. , The number of channels in the slice direction is reduced to 1/3. Therefore, the common connection of the receiving channels in the ultrasonic receiving unit 3 can be up to three channels. Note that the number of transducer channels in the scanning direction of the ultrasonic probe 1 used in this modification need not be equal to or less than １ ／ of the number of receiving circuit channels. Therefore, in FIG. 7, the description of the ultrasonic receiving unit 3 connected to the ultrasonic transducers 28 arranged in the scanning direction is omitted, and only the slice direction at an arbitrary position is shown.
[0069]
The ultrasonic receiving unit 3 includes a switching SW 32, a BPF 14, a preamplifier 15, an A / D converter 16, and a phasing adder 17, as in the first modification shown in FIG. Hereinafter, in the ultrasonic transducer 28 constituting the two-dimensional array ultrasonic probe 51, the ultrasonic transducers 28-a, 28-b, 28-c arranged in the slice direction, and the ultrasonic reception corresponding thereto. This modification will be described using a circuit as an example.
[0070]
In FIG. 7A, when the two-dimensional array ultrasonic probe 51 is connected to the ultrasonic receiving unit 3, the probe ID is transmitted to the system control unit 6, and the system control unit 6 transmits the two-dimensional array ultrasonic probe. Recognizing that the ultrasonic probe 51 has been connected, the switch SW32-a and the switch SW32 are switched so that the input terminals of the BPFs 14-a and 14-c are connected to the ultrasonic transducers 28-a and 28-c, respectively. -B is controlled. However, in this case, the BPF 14 may have a band-pass characteristic for passing only the fundamental wave, or may be bypassed.
[0071]
Therefore, the reception signals of the ultrasonic transducers 28-a to 28-c are sent to the BPF 14 via the switching SWs 32-a and 32-b or directly to the BPF 14, and further via the preamplifier 15 and the A / D converter 16. And sent to the phasing adder 17. The phasing adder 17 not only performs phasing addition of the received signals from the ultrasonic transducers 28-a to 32-c arranged in the slice direction, but also performs the phasing addition of these ultrasonic transducers 28-a to 28-c. Similarly to c, the phasing addition is also performed on the reception signals from the other ultrasonic transducers 28 arranged in the scanning direction, and the output is sent to the B-mode processing unit 4 or the Doppler mode processing unit 5.
[0072]
On the other hand, as shown in FIG. 7B, when the one-dimensionally arranged ultrasonic probe 1 is connected to the ultrasonic receiving unit 3, the probe ID is automatically sent to the system control unit 6. Further, a command signal of the S / N improvement mode is sent from the input unit 7 to the system control unit 6. The system control unit 6 receives the information and controls the switching SWs 32-a and 32-b so that the input terminals of the BPFs 14-a and 14-c are connected to the input terminals of the BPF 14-b. Further, a band-pass characteristic for extracting a harmonic component is set for the BPF 14-a and the BPF 14-c, and a band-pass characteristic for extracting a fundamental wave is set for the BPF 32-b.
[0073]
Accordingly, the received signal from the ultrasonic transducer 28 is directly sent to the BPF 14-b, and also sent to the BPFs 14-a and 14-c via the switching switches 32-32 and 32-b. Is sent to a phasing adder 17 via a preamplifier 15 and an A / D converter 16. At this time, the phasing adder 17 is separated into two, and the harmonic component of the received signal is sent to the phasing adder 17-a, and the fundamental wave component is sent to the phasing adder 17-b. In the phasing adders 17-a and 17-b, phasing addition similar to that of the first embodiment is performed on the reception signals from the other ultrasonic transducers 28 arranged in the scanning direction. The output is sent to the B mode processing unit 4 or the Doppler mode processing unit 5.
[0074]
According to this modification, the S / N ratio can be reduced even in the THI when the ultrasonic probe 1 having the normal one-dimensionally arranged ultrasonic transducers is connected to the device corresponding to the two-dimensional array ultrasonic probe 51. Significant improvements can be made. Further, as shown in FIG. 7B, when the received signals of the same ultrasonic transducer 28 are added by the phasing adder 17-a after passing through the P-channel (P = 2) receiving circuit. , The signal component after addition becomes P times, while the noise component generated from the receiving circuit is generally P times. ^1/2 Therefore, further S / N improvement is possible.
[0075]
In FIG. 7B, the BPFs 14-a and 14-c are used as harmonic component extraction filters. However, the positions and numbers of the filters are not limited. It suffices if each filter is included.
[0076]
(Second embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. In this embodiment, a case will be described in which the present invention is applied to a frequency compounding method for reducing speckle noise displayed on an ultrasonic image. In a normal ultrasonic image, it is known that a granular pattern generated by random interference of ultrasonic waves, that is, a speckle pattern is generated and hinders interpretation of an ultrasonic image. There is a frequency compound method as a method of eliminating the frequency compound.
[0077]
This method collects a plurality of ultrasonic images of the same part at different ultrasonic frequencies and adds and averages these images to generate a display image. Conventionally, a fundamental wave component of an ultrasonic reception signal from the inside of a subject is decomposed by a filter into, for example, a plurality of bands having center frequencies fo1, fo2, and fo3, and three images generated by these band components are used. Is known. However, this method has a problem that the resolution of the image is degraded because the band of the signal for generating each image is reduced to about 1/3.
[0078]
On the other hand, if the frequency compound method is performed using the fundamental wave component of the center frequency fo1 and the harmonic component of the center frequency fo2 shown in FIG. 4, the above problem can be solved. However, also in this case, improvement of the S / N of the ultrasonic image generated by the harmonic component becomes a problem.
[0079]
FIG. 8 is a diagram showing a schematic configuration of an ultrasonic diagnostic apparatus according to the second embodiment. This embodiment is different from the first embodiment in FIG. Only the changes have been made. That is, the B-mode processing unit 4 includes two-channel logarithmic converters 18-1 and 18-2 and envelope detectors 19-1 and 19-2. Further, an adder 34 for adding the signals from the two-channel B-mode processing unit 4 is newly provided.
[0080]
Hereinafter, an image generation procedure according to the present embodiment will be described. The operator connects the ultrasonic probe 1 having the above-described configuration to the ultrasonic diagnostic apparatus main body 50, and selects an imaging mode (hereinafter, referred to as a speckle reduction mode) for executing the present embodiment in the input unit 7. The system control unit 6 receives a command signal in the speckle reduction mode from the input unit 7 and reads probe ID information from the ultrasonic probe 1. Next, the system control unit 6 reads related information such as the ultrasonic frequency of the probe stored in advance in a storage circuit (not shown) in the system control circuit 6 based on the probe ID, and based on this information. The filter characteristics of the BPFs 14-1 and 14-2 are set.
[0081]
That is, the center frequency of the BPF 14-1 is set to 2fo, and the center frequency of the BPF 14-2 is set to fo. When the setting of the speckle reduction mode is completed, a scanning start command signal from the operator is transmitted from the input unit 7 to the system control unit 6, and transmission and reception of ultrasonic waves are started.
[0082]
Upon transmission of the ultrasonic wave, the rate pulse generator 11 supplies a rate pulse for determining a repetition period of the ultrasonic pulse radiated into the subject to the transmission delay circuit 12 according to a control signal from the system control unit 6. The transmission delay circuit 12 gives a delay time for converging the ultrasonic wave in the transmission and a delay time for transmitting the ultrasonic wave in a predetermined direction (θ1) to the rate pulse, and supplies the rate pulse to the pulser 13 I do.
[0083]
The pulser 13 drives the ultrasonic transducer 28 by the driving pulse, and emits an ultrasonic pulse having a center frequency fo into the subject. Also in the present embodiment, the two pulsar output lines are configured to be commonly connected to the ultrasonic probe 1, and the ultrasonic transducer is used by using only one of the two pulsars 13. 28 is performed. That is, as shown in FIG. 2, the pulsars 13-1 to 13-4 to be used for driving the transducers are selected by the control signal of the system control unit 6, and the ultrasonic pulses are generated by the driving pulses of these pulsars 13-1 to 13-4. The vibrators 28-1 to 28-4 are driven to emit ultrasonic waves into the subject.
[0084]
A part of the ultrasonic wave radiated into the subject is reflected by the tissue, and when the ultrasonic wave is reflected by a moving reflector such as a heart wall or a blood cell, the ultrasonic frequency has a Doppler shift. receive. Further, as for these ultrasonic waves, ultrasonic waves having a center frequency of 2fo are newly generated due to the non-linear characteristics of the subject tissue. Therefore, the ultrasonic wave returning to the ultrasonic probe 1 is a mixture of a fundamental component having a center frequency fo and a harmonic component having a center frequency of 2fo.
[0085]
The reception signal as described above is received by the ultrasonic transducer 28, and after the reception signal of a predetermined band is selected by the BPF 14 of the ultrasonic reception unit 3, the reception signal is amplified by the preamplifier 15 and the A / A The signal is converted into a digital signal by the D converter 16. Further, the reception signal converted into the digital signal is given a predetermined delay time by the beamformer 29 of the phasing adder 17 based on the control signal from the system control unit 6, and is added and synthesized by the adder 30.
[0086]
In FIG. 2 showing the configuration of the ultrasonic receiving unit 3 in more detail, a reception signal from the ultrasonic probe 1 composed of four ultrasonic transducers 28-1 to 28-4 is received by an 8-channel reception circuit. When supplied to the configured ultrasonic receiving unit 3, two receiving circuits are commonly connected to one ultrasonic transducer 28. That is, the reception signal from the transducer 28-1 is supplied to the BPF 14-1-1 and the BPF 14-2-1, and the reception signal from the transducer 28-2 is supplied to the BPF 14-1-2 and the BPF 14-2-2. Supplied to Similarly, the reception signal from the transducer 28-3 is supplied to the BPF 14-3 and the BPF 14-2-3, and the reception signal from the transducer 28-4 is supplied to the BPF 14-1-4 and the BPF 14-2-4. Supplied to
[0087]
In this case, the BPFs 14-1-1 to 14-1-4 are band-pass filters for extracting harmonic components of the center frequency 2fo, and the BPFs 14-2-1 to 14-2-4 are for the center frequencies fo. Is a band-pass filter for extracting the fundamental wave component of. The harmonic component of the received signal extracted by the BPF 14-1-1 is amplified to a predetermined size by the preamplifier 15-1-1 and then converted to a digital signal by the A / D converter 16-1-1. Is done. At this time, the amplification degree of the preamplifier 15-1-1 is set in advance so that the maximum amplitude of the output signal of the BPF 14-1-1 corresponds to the input dynamic range of the A / D converter 16-1-1.
[0088]
The A / D-converted received signal is supplied to an adder 30-1 after a predetermined delay time is given by a beamformer 29. The beamformer 29 receives a delay time for converging an ultrasonic wave from a predetermined depth to obtain a narrow beam width in reception, and a strong reception directivity in a predetermined direction with respect to the ultrasonic beam. This is a variable delay circuit that gives a delay time to the received signal for setting the delay time. The delay time is set by control data from the system control unit 6, and the reception directivity is first set in the θ1 direction.
[0089]
On the other hand, the output signal of the BPF 14-2-1 obtained by extracting only the fundamental wave component from the received signal obtained from the same oscillator 28-1 is amplified to a predetermined size by the preamplifier 15-2-1. , Are converted into digital signals by an A / D converter 16-2-1 and further given a predetermined delay time by a beamformer 29-2-1, and then supplied to an adder 30-2. Also in this case, the amplification degree of the preamplifier 15-2-1 is preset so that the maximum amplitude of the output signal of the BPF 14-2-1 corresponds to the input dynamic range of the A / D converter 16-1-1. .
[0090]
Similarly, the reception signals from the vibrators 28-2 to 28-4 have the BPFs 14-1-2 to 14-1-4 having the band-pass characteristics of the center frequency 2fo and the band-pass characteristics of the center frequency fo, respectively. BPF14-2-2 to BPF14-2-4, and outputs of the BPF14-1-2 to BPF14-1-4 are supplied to a preamplifier 15-1, an A / D converter 16-1, and a beamformer. It is sent to the adder 30-1 via 29-1. On the other hand, the outputs of the BPFs 14-2-2 to 14-2-4 are sent to the adder 30-2 via the preamplifier 15-2, the A / D converter 16-2, and the beamformer 29-2.
[0091]
In the adder 30-1, harmonic components are added and synthesized from the received signals received by the oscillators 28-1 to 28-4, and a harmonic received signal having reception directivity in the θ1 direction is generated. On the other hand, the adder 30-2 adds and combines the fundamental wave components to generate a fundamental wave reception signal having reception directivity in the θ1 direction.
[0092]
The harmonic reception signal of the adder 30-1 is sent to the logarithmic converter 18-1, and the fundamental wave reception signal of the adder 30-2 is sent to the logarithmic converter 18-2. Is also sent. Outputs of the adders 30-1 and 30-2 sent to the B-mode processing unit 4 are subjected to logarithmic conversion by the logarithmic converters 18-1 and 18-2 and the envelope detectors 19-1 and 19-2. After the envelope detection, the adder 34 adds and synthesizes the result, and the result is temporarily stored in the display image memory 25 of the image display unit 8 as a compound image.
[0093]
On the other hand, the adder 30-2 is sent to the Doppler mode processing unit 5 to generate a color Doppler image, and the result is temporarily stored in the display image memory 25. The description is omitted because it is the same as the embodiment.
[0094]
When the collection and storage of the compound image data and the color Doppler image data in the θ1 direction are completed, the transmission / reception direction of the ultrasonic wave is changed to θ1 + (M−1) Δθ (m = 2 to M) while sequentially updating the Δθ by Δθ. By scanning M lines, ultrasonic waves are transmitted and received in the same procedure as described above to scan the inside of the subject. At this time, the system control unit 6 collects each of the compound image data and the color Doppler image data while sequentially switching the delay times of the transmission delay circuit 12 and the beamformer 29 in accordance with the ultrasonic transmission / reception direction by the control signal. I do.
[0095]
The system control unit 6 can store the compound image and the color Doppler image in independent image memories in the display image memory 25, and can also combine and store these two types of images. When the generation of one compound image, color Doppler image, or a composite image of these has been completed in the display image memory 25, the system control unit 6 outputs predetermined image data based on an instruction signal from the input unit 7. It is read from the display image memory 25 and displayed on the monitor 27 via the display circuit 26.
[0096]
As described above, according to the present embodiment, in the frequency compound image using the fundamental wave component and the harmonic component, the S / N of the image generated from the high frequency component is remarkably improved. The S / N balance between the image generated from the component and the image generated from the harmonic component is obtained, and a good compound image can be displayed.
[0097]
As described above, the embodiments of the present invention have been described. However, the present invention is not limited to the above-described embodiments, and can be modified and implemented. For example, in the first and second embodiments, it is assumed that the A / D converter 16 is provided in the ultrasonic receiving unit 3 and the input dynamic range of the A / D converter 16 is Although the method of making the waveform amplitudes of the received waves of the harmonic component and the fundamental wave component correspond (match) has been described above, the present invention is not limited to this. For example, even in an analog ultrasonic receiving unit in which the A / D converter 16 does not exist, the preamplifier 15 itself has a finite dynamic range, and the same problem occurs. Note that the noise level in this case is determined by noise generated from the preamplifier 15 itself.
[0098]
Further, in the description of the above embodiment, the tissue harmonic imaging (THI) using the harmonic component has been described. However, the display of the Doppler signal generated from the harmonic component or the image of the Doppler signal (for example, the color Doppler image) ) And other signal forms. Further, a band-pass filter (BPF) is used as a harmonic component and fundamental wave component extracting means provided in the ultrasonic receiving unit. A high-pass filter (HPF) for extracting harmonic components and a band-pass filter for extracting fundamental wave components are used. A low pass filter (LPF) may be used.
[0099]
Insertion of the filter for extracting the fundamental wave component is desirable because it can limit the band of the quantization noise of the A / D converter or the thermal noise of the preamplifier or the like as well as the removal of the harmonic component, but all are small components. Therefore, it may be removed. Although the second harmonic component has been described as an example of the harmonic component, the harmonic component is not limited thereto, and may be a third or higher harmonic component.
[0100]
【The invention's effect】
According to the present invention, it is possible to generate and display an ultrasonic image having a good S / N from harmonic components contained in a received signal without complicating the configuration of the device.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an entire ultrasonic system according to a first embodiment of the present invention.
FIG. 2 is a diagram illustrating a configuration of an ultrasonic receiving unit according to the first embodiment of the present invention.
FIG. 3 is a diagram showing a flowchart of an image data collection procedure according to the first embodiment of the present invention.
FIG. 4 is a diagram showing a received wave spectrum according to the first embodiment of the present invention.
FIG. 5 is a view showing a mechanism of S / N improvement in the first embodiment of the present invention.
FIG. 6 is a diagram showing a first modification of the first embodiment of the present invention.
FIG. 7 is a diagram showing a second modification of the first embodiment of the present invention.
FIG. 8 is a diagram illustrating a configuration of an entire ultrasonic system according to a second embodiment of the present invention.
[Explanation of symbols]
1 Ultrasonic probe
2 Ultrasonic transmitter
3 Ultrasonic receiver
4 B-mode processing unit
5 Doppler mode processing unit
6 System control unit
7 Input section
8 Image display section
13 Pulsa
14 BPF (Band Pass Filter)
15 Preamplifier
16 A / D converter
17 phasing adder
28 Ultrasonic transducer
29 Beamformer
30 adder
31 Connector

Claims (8)

An ultrasonic probe including an ultrasonic vibrator for transmitting and receiving ultrasonic waves, an ultrasonic transmitting unit for driving the ultrasonic vibrator and transmitting an ultrasonic pulse having a first center frequency,
A plurality of reception channels having harmonic component extraction means for extracting a reception signal having a frequency substantially an integral multiple of the first center frequency from an ultrasonic signal received by the ultrasonic vibrator. First ultrasonic receiving means provided;
A second ultrasonic receiving unit including a plurality of reception channels for receiving a reception signal having a frequency component substantially equal to the first center frequency from an ultrasonic signal received by the ultrasonic transducer;
First image data generation means for generating image data for a reception signal obtained by the first reception means;
Second image data generation means for generating image data for a reception signal obtained by the second reception means;
Display means for displaying at least one of first image data generated by the first image generation means and second image data generated by the second image generation means,
An ultrasonic transducer, wherein one or more ultrasonic transducers of the ultrasonic probe are connected in parallel to a predetermined receiving channel of the first ultrasonic receiving means and a predetermined receiving channel of the second ultrasonic receiving means. Ultrasound diagnostic device. The first image data generating unit generates image data for displaying a B-mode image, and the second image data generating unit generates image data for displaying a color Doppler image. The ultrasonic diagnostic apparatus according to claim 1, wherein An ultrasonic probe incorporating a plurality of ultrasonic transducers,
Ultrasonic transmitting means for driving the ultrasonic transducer to transmit an ultrasonic pulse having a first center frequency;
A plurality of reception channels having harmonic component extraction means for extracting a reception signal having a frequency substantially an integral multiple of the first center frequency from an ultrasonic signal received by the ultrasonic vibrator. A first ultrasonic receiving means provided;
A second ultrasonic receiving unit including a plurality of receiving channels for receiving an ultrasonic signal having a frequency component substantially equal to the first center frequency from an ultrasonic signal received by the ultrasonic transducer;
First image data generation means for generating image data for a reception signal obtained by the first reception means;
Second image data generation means for generating image data for a reception signal obtained by the second reception means;
Combining means for adding and combining first image data generated by the first image generating means and second image data generated by the second image generating means; Display means for displaying third image data, wherein one or more ultrasonic transducers of the ultrasonic probe are connected to a predetermined reception channel of the first ultrasonic reception means and a predetermined reception channel of the second ultrasonic reception means. An ultrasonic diagnostic apparatus connected in parallel with a receiving channel. 4. The ultrasonic diagnostic apparatus according to claim 3, wherein the first image data generating unit and the second image data generating unit generate image data for displaying a B-mode image. 4. The ultrasonic diagnostic apparatus according to claim 1, wherein the harmonic component extracting means has a filter function of reducing the first frequency component and extracting a second frequency component. The ultrasonic diagnostic apparatus according to claim 4, wherein the harmonic component extracting means is a band-pass filter that extracts a received signal having the second center frequency. The first ultrasonic receiving means includes a changeover switch at an input stage thereof, and receives a signal from one or more ultrasonic transducers of the ultrasonic probe through the changeover switch to the first ultrasonic wave. 4. The ultrasonic diagnostic apparatus according to claim 1, wherein a predetermined receiving channel of the receiving unit and a predetermined receiving channel of the second ultrasonic receiving unit are supplied in parallel. Performs phasing addition processing on ultrasonic signals obtained from a plurality of ultrasonic transducers to generate an ultrasonic reception signal corresponding to a predetermined scanning line, and generates an ultrasonic image based on the ultrasonic reception signal. In an ultrasonic diagnostic apparatus that
A first and a second reception channel for processing an ultrasonic signal from one ultrasonic transducer are provided at a stage preceding the addition processing in the phasing addition processing,
The first receiving channel includes a converter that converts an ultrasonic signal from the ultrasonic transducer into a digital signal, and the second receiving channel processes an ultrasonic signal from the ultrasonic transducer. An ultrasonic diagnostic apparatus comprising: a filter; and a converter for converting an output of the filter into a digital signal.

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