JPH0696010B2 - Ultrasonic diagnostic equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Object of the Invention (Industrial field of use) The present invention is an ultrasonic wave for collecting a reflection component of an ultrasonic wave transmitted toward a subject and reflecting the reflected component from the subject. Regarding diagnostic equipment.

(Prior Art) In an ultrasonic diagnostic apparatus, an ultrasonic wave is transmitted toward a subject by applying a driving pulse (also referred to as an excitation pulse), and an ultrasonic wave that receives a reflection component from the subject is received. A sonic probe is provided.

In an actual ultrasonic diagnostic apparatus, a plurality of ultrasonic probes of different types are prepared and used properly according to the site to be diagnosed and the application.

The ultrasonic probe basically comprises a probe head having one or a plurality of ultrasonic transducers and a cable connected to the probe head. A connector is attached to the other end of the cable, and the ultrasonic probe is attachable to and detachable from the apparatus body by this connector. Therefore, the replacement of the ultrasonic probe can be easily performed by this connector.

By the way, the ultrasonic probe is classified into a resonance type and a non-resonance type.

A resonance type ultrasonic probe is shown in FIG. A probe 36 is formed having an ultrasonic transducer 34 and a coil 35 connected in parallel to the ultrasonic transducer 34 via a cable 38.

The probe 36 is coupled to the main body of the device via a connector 39. The ultrasonic transducer 34 and the cable 38 can be regarded as a kind of capacitor, and a parallel resonant circuit is formed by this and the coil 35, so that damping vibration is generated by application of a drive pulse (for example, a square wave pulse in the positive direction). As a result, as shown in FIG. 8, a resonance potential (2VH) about twice as high as the drive pulse (pulse potential is VH) is generated between the probe terminals.

On the other hand, in the non-resonant type ultrasonic probe, for example, as shown in FIG. 7, the probe head 37 is formed only by the ultrasonic transducer 34, and there is no equivalent to the coil 35 in FIG. Since it is a non-resonant type, the potential between the probe terminals when the drive pulse is applied is almost equal to the potential (VH) of the drive pulse as shown in FIG.

In this way, the resonance type and the non-resonance type have different potentials between the probe terminals when a drive pulse of the same potential is applied, so in a normal device, the potential of the drive pulse may be changed according to the type of ultrasonic probe. There is. In other words, in order to prevent damage to the IC (integrated circuit) and transistors of the transmission / reception system due to the resonance potential (2VH), the potential of the drive pulse for the resonance type ultrasonic probe is kept lower than that of the non-resonance type. I am trying. If an IC or the like that can sufficiently tolerate the resonance potential is applied to the transmission / reception system, it is not necessary to make the potential of the drive pulse different, but in reality it is difficult to manufacture such a high breakdown voltage IC, etc. The reality is that the potential of the drive pulse must be adjusted.

Usually, an ultrasonic probe is provided with a probe ID for automatic identification of the probe. This probe ID consists of 6 to 8 bits at the logic level. When the connector on the ultrasonic probe side is connected to the device body, the CPU of the device body
The (central processing unit) recognizes the ID of the ultrasonic probe, and by this recognition, the driving condition suitable for the ultrasonic probe is automatically set. The drive pulse adjustment depending on the difference between the resonance type and the non-resonance type is also automatically performed based on the recognition result of the probe ID.

(Problems to be Solved by the Invention) However, in the conventional device, since the connection between the ultrasonic probe and the device main body is due to mechanical contact of the connector, contact failure is likely to occur at this connection portion, and particularly the connector pin. If a contact failure occurs in the probe ID system of, the device body may erroneously recognize the probe. Also,
Misidentification of the ultrasonic probe type is also caused by a wiring error in the ID system inside the probe.

For example, if the ultrasonic probe actually mounted is of the resonance type, but is mistakenly recognized as the non-resonance type, the drive pulse higher than the resonance type predetermined potential is concerned. Since it is applied to the ultrasonic probe, there is a possibility that the above-mentioned resonance potential (2VH) may damage the IC of the transmission / reception system.

Ultrasonic probe type
A method is conceivable in which a parity bit is added to the ID and the probe ID is read and checked using this parity bit, or an ID method using an analog signal instead of an ID using a logic bit.

However, although the method of adding a parity bit reduces the probability of probe misidentification probabilistically, the recent multi-element probe requires many connector pins and the number of probes also increases, so the parity bit This is difficult to achieve because there are no extra pins, and if the number of pins on the connector is increased, the compatibility with existing ultrasonic probes will be lost.

In addition, the method using the ID method using an analog signal is difficult to realize because the compatibility with the existing ultrasonic probe is lost.

Therefore, the present invention eliminates the above-mentioned drawbacks, and an object thereof is to prevent the transmission / reception system from being damaged due to erroneous recognition of the type of the ultrasonic probe without losing the compatibility with the existing ultrasonic probe. Another object is to provide an ultrasonic diagnostic apparatus.

[Structure of the Invention] (Means for Solving the Problem) The present invention recognizes a probe identification signal of a connected ultrasonic probe and sets different drive conditions depending on whether the ultrasonic probe is a resonance type or a non-resonance type. In the ultrasonic diagnostic apparatus which has a driving condition setting means for driving the ultrasonic probe under the driving condition set by the driving condition setting means to collect ultrasonic information of a subject, First discrimination means for discriminating whether the ultrasonic probe is a resonance type or a non-resonance type on the basis of a voltage between the probe terminals obtained by passing a predetermined current, and a result of the type discrimination by the discrimination means is the drive condition setting. The second discriminating means for discriminating whether or not the result is the type recognized by the means, and based on the discrimination result of the second discriminating means, when the type coincides, And a control means for controlling the ultrasonic probe to be driven under the drive condition set by the drive condition setting means, and to prohibit the drive of the ultrasonic probe in case of type mismatch. Characterize.

(Operation) When the ultrasonic probe is attached to the apparatus main body, the ultrasonic probe is energized, and the type of the ultrasonic probe is determined by the terminal voltage at that time. This determination is performed separately from the conventional probe ID.

Then, it is determined whether or not this determination result matches the type recognition result by the probe ID recognized by the drive condition setting means, and in the case of type match, the drive set by the drive condition setting means is determined. The ultrasonic probe is driven under the conditions, and the driving of the ultrasonic probe is prohibited when the types do not match. As a result, it is possible to prevent the transmission / reception system from being damaged due to erroneous recognition of the type of the ultrasonic probe.

In addition, the type of ultrasonic probe is
Since it is performed separately from the ID method and does not involve adding a parity bit or changing the probe ID method, compatibility with existing ultrasonic probes is not lost.

(Example) Hereinafter, the present invention will be specifically described based on an example shown in the drawings.

FIG. 1 is a block diagram of an ultrasonic diagnostic apparatus which is an embodiment of the present invention. In the figure, reference numeral 21 denotes an ultrasonic probe in which a plurality of ultrasonic transducers (hereinafter referred to as transducers) 5-1 to 5-n are arranged in an array, and 2-1 to 2-m.
Is a transmission delay unit that delays the vibration timing of the vibrators 5-1 to 5-n, and 3-1 to 3-m are the vibrators 5
It is a pulser that generates drive pulses used for excitation of -1 to 5-n. Reference numeral 4 is a high-voltage switch group for switching and connecting the vibrators. Reference numerals 6-1 to 6-m denote preamplifiers for amplifying ultrasonic echo signals (ultrasonic information) input from the transducers 5-1 to 5-n via the high voltage switch group 4, and 7-1 to 7-m. -M is the preamplifier 6-1 to 6-
A reception delay unit that delays the output of m, and an adder 8 that adds the outputs of the reception delay units 7-1 to 7-m.
Reference numeral 9 is an echo signal processing unit that takes in the output of the adder 8 and processes an echo signal, 10 is a digital scan converter mainly composed of a frame memory, and 11 is a digital scan converter 10. It is a display unit that visualizes the output.

In FIG. 1, the portion other than the ultrasonic probe 21 is the apparatus main body, and the ultrasonic probe 21 is detachably coupled to the apparatus main body by the connector 1. Ultrasonic probe 21
The probe ID for identifying the type of is recognized by the CPU 13. The probe ID and its recognition are the same as in the conventional device. The CPU 13 functionally has a transmission / reception control means 12 and a drive condition setting means 15. The transmission / reception signal means 12 includes the high-voltage switch group 4 and the transmission delay unit 2-1.
To 2-m, reception delay units 7-1 to 7-m, and the like. The drive condition setting means 13 recognizes the type of the ultrasonic probe based on the probe ID, sends the recognition result b to the transmission prohibition control circuit 17 described later, and sets the drive condition of the ultrasonic probe based on the recognition result. Is to do. Note that the driving conditions referred to here include the potential of the driving pulse.

Further, in the apparatus of this embodiment, the apparatus main body side of the connector 1 and the CPU 1
A tester circuit 16 and a transmission prohibition control circuit 17 are provided between them and As will be described later in detail, the tester circuit 16 energizes an ultrasonic probe 21 coupled to the apparatus main body by the connector 1 so that the ultrasonic probe 21 can be connected.
Type (resonant type or non-resonant type). However, the determination result a of the lever tester circuit 16 is
It is adapted to be transmitted to the transmission prohibition control circuit 17. The transmission prohibition control circuit 17, the probe determination result in the tester circuit 16, when the drive condition set by the drive condition setting means 15 is inappropriate, ultrasonic probe drive under the drive condition concerned. It is forbidden.
That is, in the transmission prohibition control circuit 17, the tester circuit
The output a of 16 and the output b of the drive condition setting means 15 are compared, and if the two match in this comparison, the transmission inhibition control circuit 17 allows the transmission / reception control means 12 to drive the ultrasonic probe. However, if the two do not match, the drive of the ultrasonic probe is prohibited.

Next, the detailed configuration of the tester circuit 16 will be described with reference to FIG.

Reference numeral 29 is a comparator, and the anode of the diode 23 and one end of the resistor 27 are connected to one input terminal of the comparator 29. The other end of the resistor 27 is grounded.
The power supply 28 is connected between the other input end of the comparator 29 and the ground line. A diode 22 is provided at the input of this tester circuit 16 and the cathode of this diode is
The cathode of the diode 23 and one end of the resistor 24 are connected to 22. The other end of the resistor 24 is connected to the switch 25. One contact 25a of the switch 25 is grounded, and the other contact 25b is connected to the negative side of the power supply 26. The output end of the comparator 29 becomes the output end of the tester circuit 16.

Next, the operation of the embodiment apparatus configured as described above will be described.

3 and 4 are circuit diagrams for explaining the operation of the tester circuit 16, and FIG. 5 is a tester circuit 16 and a transmission prohibition circuit 17.
It is a flow chart which shows an operation of.

When the ultrasonic probe 21 is connected to the apparatus main body, before transmission / reception of ultrasonic waves is performed by the ultrasonic probe 21,
The probe ID is recognized by the drive condition setting means 15 in the CPU 13. Then, the identification signal (b) indicating whether the ultrasonic probe 21 is the resonance type or the non-resonance type is sent to the transmission prohibition control circuit, and the transmission / reception control means 12 is set with the driving condition based on the recognition result. .

On the other hand, almost simultaneously with the above probe ID recognition, the tester circuit
The type (resonance type or non-resonance type) of the ultrasonic probe 21 is determined by operating 16 (S1).

When a non-resonant type ultrasonic probe is attached to the main body of the device, the transmission system is a transducer 5 as shown in FIG.
1, the equivalent resistance 30 of the transmission system is connected in parallel. When the switch 25 in the tester circuit 16 selects the contact 25b, the current from the power supply 26 flows in the path of the resistor 30 → the diode 22 → the resistor 24. As a result, a voltage determined by the resistance ratio of the resistors 30 and 24 appears across the resistor 30 (ignoring the forward voltage drop of the diode), and this is the comparator 29.
Is transmitted to one of the input terminals. This voltage is V ₁ (negative potential with respect to ground). If the circuit constants are set so that | V ₁ |> | Vref | holds when the voltage of the power supply 38 is Vref, the output state of the comparator 29 in this case becomes a high level. The switch 25 is the contact 25a.
When is selected, the voltage V ₁ is not applied to _one input terminal of the comparator 29, so that the output state of the comparator 29 becomes low level.

When the resonance type ultrasonic probe is attached to the main body of the apparatus, the coil 33 exists as shown in FIG. 4, and the DC resistance of the coil 33 is almost zero. Even though 25b is selected, ｜ V
_{2 When} || Vref | is established, the output state of the comparator 29 becomes low level.

Therefore, the output state of the comparator 29 determines the type of the ultrasonic probe. This determination result a is transmitted to the transmission prohibition control circuit 17. Then, the transmission prohibition control circuit 17 compares the output a of the test circuit 16 with the output b of the drive condition setting means 15 to determine whether or not the drive condition is appropriate (S2). In this determination, if the drive condition is appropriate (a = b), the ultrasonic probe drive under the drive condition previously set by the drive condition setting means 15 is allowed (S3), and conversely the drive condition is If it is inappropriate (a ≠ b), the ultrasonic probe drive under the drive condition is prohibited (S4). Therefore, the drive condition setting means
Even if the ultrasonic probe type is misidentified due to misreading of the probe ID in 15, the IC in the transmission / reception system
Damage such as is prevented in advance. In addition, the tester circuit 16
The probe discrimination in (1) is performed separately from the probe ID, and does not involve adding a parity bit or changing the probe ID method, so compatibility with existing ultrasonic probes is not lost.

Incidentally, when the drive of the ultrasonic probe 21 is allowed by the transmission prohibition control circuit 17, under the control of the transmission / reception control means 12, ultrasonic transmission / reception by the ultrasonic probe 21 is performed, and an echo signal obtained by this Based on ultrasonic display
It will be displayed on 11.

Although one embodiment of the present invention has been described above, it is needless to say that the present invention is not limited to the above embodiment and various modifications can be made.

For example, in the above embodiment, the transmission prohibition control circuit 17 sends a control signal to the transmission / reception control means 12 to inhibit the ultrasonic probe from being driven, but if the drive pulse is not applied to the ultrasonic probe, Since the driving can be prohibited, the high-voltage switch 4 and the pulsers 3-1 to 3-m may be directly actuated.

Further, in the above embodiment, the transmission prohibition control circuit 17 is used for description, but the transmission prohibition control circuit 17 may be functionally realized in the CPU 13.

Further, in the above-described embodiment, only the channel corresponding to the transducer 5-1 in the ultrasonic probe 21 is described as the measurement target of the tester circuit 16, but the probe discrimination may be performed by measuring the two or more channels. You may

The tester circuit 16 may be installed between the high voltage switch group 4 and the pulsar group 3.

[Effects of the Invention] As described in detail above, according to the present invention, it is possible to prevent the transmission / reception system from being damaged due to misidentification of the type of the ultrasonic probe without losing compatibility with the existing ultrasonic probe. .

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of an ultrasonic diagnostic apparatus according to the present invention, FIG. 2 is a detailed circuit diagram of a main part of FIG. 1,
FIGS. 3, 4 and 5 are circuit diagrams and flowcharts for explaining the operation of the main part of the apparatus of this embodiment, and FIGS. 6 and 7 are circuit diagrams showing the difference in the type of ultrasonic probe,
FIGS. 8 and 9 are waveform diagrams of the potential between the probe terminals when the ultrasonic probe of FIGS. 6 and 7 is driven, respectively. 12 ... Transmission / reception control means, 15 ... Driving condition setting means, 16 ... Tester circuit, 17 ... Transmission prohibition control circuit, 21 ... Ultrasonic probe.

Claims (1)

[Claims] 1. A drive condition setting means for recognizing a probe identification signal of a connected ultrasonic probe and setting different drive conditions depending on whether the ultrasonic probe is a resonance type or a non-resonance type. In an ultrasonic diagnostic apparatus that drives the ultrasonic probe under driving conditions set by means to collect ultrasonic information of a subject, a voltage between the probe terminals obtained by passing a predetermined current through the ultrasonic probe Based on the first discriminating means for discriminating whether the ultrasonic probe is a resonance type or a non-resonant type, whether the result of type discrimination by the discriminating means matches the result of type recognition by the drive condition setting means. Based on the discrimination result of the second discrimination means and the discrimination result of the second discrimination means, if the types match, the drive condition set by the drive condition setting means is set. Wherein under conditions ultrasonic probe is driven, the ultrasonic diagnostic apparatus characterized by comprising a control means for controlling so that the drive of the ultrasonic probe is inhibited in the case of type mismatch.