JPH074385B2 - Ultrasonic diagnostic equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Outline] An ultrasonic diagnostic apparatus for performing dynamic focusing, which aims to effectively eliminate the influence of noise at the time of multiplexer switching on the output by a configuration that is inexpensive and easy to control, An ultrasonic pulse is incident toward the inside of the subject, a reflection pulse from the inside of the subject due to the ultrasonic pulse is received by a row of a plurality of ultrasonic transducers, and the ultrasonic waves received by each of the ultrasonic transducers are received. A plurality of delaying means for delaying the electric signal output according to the sound wave so as to extract the electric signal corresponding to the reflected pulse from each small region of the diagnosis target portion inside the subject, and the electric signal A multiplexer that selects one of the outputs that have passed through the plurality of delay units, and sequentially switches the outputs of the multiplexers to sequentially select all the small portions of the diagnosis target portion. In the ultrasonic diagnostic apparatus for obtaining the image of the diagnosis target part by obtaining the intensity of the reflected pulse from the region, the multiplexer is composed of a pair that simultaneously selects the same output according to the same control signal, and one of the pair The output through the delay means is applied to the input terminal, and the inverted output of the delay means is applied to the other of the pair, and the output of each multiplexer of the pair is inverted. A differential amplifier for applying to the input terminal and the non-inverting input terminal is provided.

[Industrial application field]

The present invention relates to an ultrasonic diagnostic apparatus, and more particularly to an ultrasonic diagnostic apparatus that performs dynamic focusing.

In an ultrasonic diagnostic apparatus used to obtain a cross-sectional image of the inside of a human body, a large number of micro-vibrators (ultrasonic vibrators) are arranged linearly and the timing of transmission from these many micro-vibrators is concave. By sending out the ultrasonic pulse shifted, the ultrasonic beam is focused on a specific small area (focal area) inside the human body. At this time, the ultrasonic pulse reflected from the focal region reaches the row of the micro-vibrator with a fan-shaped wave front centered on the focal region, so that the micro-vibrators arranged in a line simultaneously from the focal region. The reflected ultrasonic pulse is received with a delay corresponding to the fan-shaped wavefront. Therefore, in order to obtain the intensity of the reflected pulse from the focal region, a delay that compensates for the above delay is applied to the output signal (received signal) from each micro-vibrator, and all micro-vibrator outputs are output. The timings of the received signals corresponding to the reflected pulses from the focal area in the output are matched, and then the received signals corresponding to the reflected pulses from the focal area from all the microvibrators whose timings match are added. Is done. The above-mentioned "delay for compensating for delay" is realized by a delay circuit group provided so that a combination of delay times is set corresponding to each focal region and can be connected to each microvibrator output.

Further, in order to obtain an image of the internal cross-section of the human body, since the reflection pulse from the one focal area corresponds to only one pixel, the focal area is moved one after another and the entire range of the image desired is obtained. The level of the reflected pulse from the focal area must be determined. The movement of the focal areas is realized by sequentially switching the outputs of the delay circuit groups provided corresponding to the respective focal areas using a multiplexer. This is called dynamic focus.

However, when switching by the multiplexer, spike noise is essentially generated due to the switching.
This noise deteriorates the image quality of the obtained image, and conventionally, effective means for preventing the deterioration of the image quality due to this noise has been demanded.

[Conventional technology]

FIG. 4 shows an example of a configuration for suppressing the influence of noise at the time of switching by the multiplexer from appearing in the output in the conventional ultrasonic diagnostic apparatus. In the figure, the reception signal from each micro-vibrator of the ultrasonic transducer array 7 including a large number of micro-vibrators as described above is amplified by the reception amplifier 6, and 2n (not necessarily an even number). It is not necessary, and may be 2n-1.) It is input in parallel to the delay circuit group D ₁ , ... D ₂ n. Here, each delay circuit group D ₁ , ... D ₂ n is provided corresponding to each focal area as described above, and the output from each micro-vibrator by the ultrasonic pulse reflected from each focal area at the same time. The delay time is set so as to match the signal timing. The adder 52 adds all the output pulses whose timings match and determines the level of the reflection pulse from each focal region.

Adder that determines the level of the reflected pulse from each of the above focal areas
The output of 52 is applied to the first multiplexer 12 for the odd-numbered order of moving the focal area and to the second multiplexer 13 for the even-numbered order. Further, the outputs of the first and second multiplexers are applied to a two-input third multiplexer 14, and the output of the third multiplexer 14 is used to form each pixel for forming an image of the ultrasonic diagnostic apparatus on the display. The brightness levels of are sequentially given.

Here, the outputs of the multiplexers 12, 13, 14 having the configuration shown in FIG. 4 are controlled by the control circuit 4 so as to be switched at the timing shown in FIG. That is,
First multiplexer 12 and second multiplexer 13
, The focal region movement, that is, the switching timing of the multiplexer output is shifted, respectively.
The multiplexer 14 is controlled so as to select and output one of the outputs of the first and second multiplexers 12 and 13 which does not include the timing of switching (hence, noise at the time of switching). As a result, noise at the time of switching in the first and second multiplexers 12 and 13 becomes the fourth noise.
It does not appear in the output of the configuration in the figure. However, in the configuration of FIG. 4, the influence of noise when switching the output of the third multiplexer 14 remains. Therefore, in the configuration of FIG. 4, the third multiplexer 14 is
Especially, the one having a low noise level generated at the time of switching is selected and used. Although such a multiplexer having a low noise level is generally expensive, in the configuration of FIG. 4, it is used only for a two-input multiplexer that obtains a final output.

[Problems to be solved by the invention]

As described above, in the conventional configuration, it is inevitable to use an expensive multiplexer with a particularly low noise level in order to suppress noise when switching multiplexers, and even if such a multiplexer is used, It cannot be said that the suppression of the influence of noise on the output is sufficient. Further, in the configuration using a plurality of multiplexers as shown in FIG. 4, there is also a problem that its control becomes complicated.

The present invention has been made in view of the above problems, and provides an ultrasonic diagnostic apparatus that effectively removes the influence of the output of noise at the time of multiplexer switching with a configuration that is inexpensive and easy to control. It is intended.

[Means for solving problems]

In the present invention, in an ultrasonic diagnostic apparatus that performs dynamic focusing, a diagnostic target portion inside a subject is generated with respect to an electric signal output from each of a plurality of ultrasonic transducers in response to reception of ultrasonic reflected pulses. A multiplexer 10 for selecting one of the outputs of a plurality of delaying means for delaying the extraction of an electric signal corresponding to the reflected pulse from each of the small regions, and simultaneously selecting the same output according to the same control signal. A pair of multiplexers are provided, and one of the outputs of the delay means 5 is input to one input end of the pair, and the other of the outputs of the delay means 5 is inverted to the other of the pair. A differential amplifier 2 is provided for applying and further applying the outputs of the pair of multiplexers to the inverting input terminal and the non-inverting input terminal, respectively.

[Action]

FIG. 1 is a diagram showing the principle of removing spike noise when switching multiplexers according to the present invention. Two switches SW1 and SW2 that open / close at the same time according to the same control signal are applied, and a signal at the contact on one side of each and a signal obtained by inverting that signal with the inverter 3 are applied The spike noise is basically the same although there is a slight difference due to the difference in shape between the two contacts. By the way, the signal components have opposite polarities in the paths of SW1 and SW2, but the above noise components have the same polarity. Therefore, the above two switches SW1
If the difference between the signals that have passed through and SW2 is obtained by the differential amplifier 2, the noise component having the same polarity is canceled and only the signal component having the opposite polarity remains.

The present invention applies the above-mentioned principle to the output of a plurality of delay means 5 which outputs signals corresponding to the brightness of the pixels of the ultrasonic diagnostic image and corresponding to the intensity of the ultrasonic reflected pulse from each small region of the diagnosis target portion. This is applied to a multiplexer that sequentially selects and outputs one by one, and the output of each delay unit 5 is
An inverted version of the output of the delay means 5 is applied to the input terminals of one of the pair of multiplexers that select the same output at the same time in response to the same control signal.
The voltage is applied to the input terminal corresponding to the input terminal on the one side. Thus, since the spike noises at the time of switching the multiplexer, which are superimposed on both of the pairs, have the same polarity as in the principle of FIG. 1, they are canceled by each other in the next differential amplifier 2 and output to the output. Does not appear. The output of the differential amplifier 2 appears only in the output of the delay means 5 which is inverted and input.

As described above, according to the present invention, spike noise generated when the multiplexer is switched can be effectively removed.

〔Example〕

FIG. 2 is a block diagram of the first embodiment of the ultrasonic diagnostic apparatus of the present invention. In the figure, 2 is a differential amplifier, 4 is a control circuit, 5 is a delay / addition circuit group, 6 is a reception amplifier, 7 is an ultrasonic transducer array, 10 is a multiplexer, 30 is an inverting circuit group, 71
Is a transmission / reception switching circuit, 72 is a transmission amplifier, 73 is a pulse generation circuit, and 80 is a subject.

The pulse generation circuit 73 is controlled by the control circuit 4
A high frequency pulse of several MHz is output every 100 μsec. This high-frequency pulse is amplified by the transmission amplifier 72 and further applied to each ultrasonic transducer of the ultrasonic transducer array 7 via the transmission / reception switching circuit 71. As described above, the ultrasonic transducer array 7 is composed of a large number of minute ultrasonic transducers arranged in a line. In each ultrasonic transducer, the above-mentioned high-frequency pulse excites vibration of the ultrasonic frequency. This vibration is incident on the inside of the subject 80 as an ultrasonic pulse. The reflected pulse reflected inside the subject 80 is received by each ultrasonic transducer,
Each is converted into an electric signal (reception signal), amplified by the reception amplifier 6 via the transmission / reception switching circuit 71, and applied to the delay / addition circuit group 5. The delay / addition circuit group 5 provides a combination of delays for extracting reflected pulses from each focal region inside the subject 80 as described above to each of the received signals from the ultrasonic transducers, A delay circuit group consisting of a combination of delay circuits corresponding to each focal area and a sum of reception signals corresponding to a specific focal area from each of the micro ultrasonic transducers whose timings are matched by the combination of the delay circuits are calculated. The series connection with the output adder is arranged in parallel for the number of focal areas (the delay circuit groups D ₁ , ... D ₂ n51, in FIG. 4 described above).
And adder 51, but in the embodiment of FIG.
It is not necessary to divide it into odd and even numbers). This delay
The adder circuit group 5 corresponds to the delay means 5 described above in [Means for solving the problem] and [Operation].

According to the present invention, the outputs corresponding to the sum of the received signals from the focal areas of the delay / addition circuit group 5 are respectively branched into two systems, one on the switch 1 side of the multiplexer 10 and the other on each of the outputs. After being inverted respectively in the inversion circuit group 30 composed of a row of inverters for inverting, the signal is applied to the switch 2 side of the multiplexer 10. Multiplexer
The switch 1 side and switch 2 side of 10 have exactly the same configuration, and simultaneously select and output the analog signals applied to the same terminal among those applied to the respective input terminals according to the same control input. It is an analog multiplexer. For example, it is realized by connecting a commercially available MB84052B type dual 4-channel multiplexer in parallel as many as necessary according to the number of focal areas. Control circuit 4
Control of the multiplexer 10 from the switch 1 side and the switch 2 side of the multiplexer 10, the sum of the received signals by the reflected pulses from the same focal region (equal to one of the outputs of the delay / addition circuit group 5) and the reception An inverted version of the sum of the signals is output and applied to the inverting input terminal and the non-inverting input terminal of the differential amplifier 2, respectively. In the differential amplifier 2,
As described above with reference to the principle explanatory diagram of FIG. 1, the components of spike noise of the same polarity, which are generated by switching the outputs on the switch 1 side and the switch 2 side of the multiplexer 10 and are superimposed on the signal, are canceled. Then, only the received signal component is output.

As described above, according to the configuration of FIG. 2, the influence on the output of noise at the time of multiplexer switching can be effectively removed by the configuration which is inexpensive and easy to control.

FIG. 3 is a block diagram of the second embodiment of the present invention. In the figure, 2 is a differential amplifier, 4 is a control circuit, 11, 12, 13 are multiplexers, 31, 32 are inverters, 51 is a delay circuit group, and 52 is an adder. The configuration shown in this figure is obtained by applying the principle shown in FIG. 1 as a feature of the present invention to the conventional configuration shown in FIG. In this figure, the configuration on the transmitting side and the stage before the receiving amplifier on the receiving side are omitted, but these are the same as the configuration in FIG. In the configuration of FIG. 3,
The first and second multiplexers 12 and 13 are exactly the same as those in FIG. 4, but the outputs of these multiplexers 12 and 13 are branched into two systems according to the present invention, and each system is the fourth system. On the switch 1 side of the multiplexer 11 of each of the other systems, the inverters 31, 32 are respectively connected.
Is applied to the switch 2 side of the fourth multiplexer 11 via. The multiplexer 11 has the same configuration having two input terminals and one output terminal on each of the switch 1 side and the switch 2 side, and selects the signals applied to the same input terminal simultaneously by the same control by the control circuit 4. It is an output analog multiplexer. Under the control of the control circuit 4, the switch 1 side of the multiplexer 11 and the switch 2
From each of the sides, the first and second multiplexer 1
An output from one of the output terminals 2 and 13 and an inverted output from the one output are output and applied to the inverting input terminal and the non-inverting input terminal of the differential amplifier 2, respectively. Also in this case, as in the case of FIGS. 1 and 2, the spike noises generated on the switch 1 side and the switch 2 side and superposed on the signal have the same polarity, so that these spike noises are generated in the differential amplifier 2. Is canceled and only the received signal component is output.

In the configuration of FIG. 3, the control complexity is similar to that of the configuration of FIG. 4, but spike noise generated when switching the third multiplexer 14 of FIG. 4 is effectively eliminated. Also, it is not necessary to use expensive parts for this part.

〔The invention's effect〕

According to the present invention, the influence on the output of the noise generated at the time of switching the multiplexer is effectively eliminated by the structure which is inexpensive and easy to control.

[Brief description of drawings]

FIG. 1 is a diagram illustrating the principle of the present invention, FIG. 2 is a configuration diagram of a first embodiment of the present invention, FIG. 3 is a configuration diagram of a second embodiment of the present invention, and FIG. 4 is a conventional multiplexer switching. FIG. 5 is a diagram showing a configuration example for noise suppression, and FIG. 5 is a switching timing diagram of each multiplexer in FIG. (Description of symbols) 1 ... Switch, 2 ... Differential amplifier, 3 ... Inverter, 4 ... Control circuit, 5 ... Delay / adding circuit group, 6 ...
Receiver amplifier, 7 ... Ultrasonic transducer array, 10,11 ... Multiplexer pair, 12,13, 14 ... Multiplexer, 30 ... Inversion circuit group, 31,32 ... Inverter, 51 ... Delay circuit group, 52
...... Adder, 71 ...... Transmission / reception switching circuit, 72 ...... Transmission amplifier,
73 ... Pulse generator, 80 ... Subject.

Claims (1)

[Claims] 1. An ultrasonic pulse is directed toward the inside of a subject (80), and the reflected pulse from the inside of the subject (80) due to the ultrasonic pulse is transmitted to a row (7) of a plurality of ultrasonic transducers. The subject (80) receives an electric signal received by each of the ultrasonic transducers and is output according to the received ultrasonic wave.
A plurality of delay means (5) for delaying to extract an electric signal corresponding to a reflection pulse from each small region of the internal diagnosis target portion, and the plurality of delay means (5) for the electric signal.
Multiplexer (10) for selecting one of the outputs via
And an ultrasonic diagnostic apparatus for obtaining an image of the diagnosis target portion by obtaining the intensities of reflected pulses from all the small areas of the diagnosis target portion by sequentially switching the output of the multiplexer, the multiplexer (10) Consists of a pair for selecting the same output at the same time in response to the same control signal. One of the inputs of the pair is the output that has passed through the delay means (5), and the other of the pair is the delay means. A differential amplifier (2) is provided which applies the inverted outputs of (5) and further applies the outputs of the pair of multiplexers to the inverting input terminal and the non-inverting input terminal, respectively. An ultrasonic diagnostic apparatus characterized by: