DE4316643A1 - Diagonal ultrasonic system with acoustic command unit - has commands entered via microphone with processing unit to generate digital input transmitted to control unit - Google Patents

Abstract

The ultrasonic diagnostic system (2) has an ultrasonic application stage (4), a transmit/receive stage (6), signal processor (8) and a monitor (10) for output evaluation. The internal control stage (14) responds to commands from an operator panel (12) and also from a remote control unit (20). The remote control unit generates transmission signals via an interface (40) that are received by the built in control unit (14). The remote controller has a microprocessor (30), command memory (36), display (34), and speech synthesiser (38). Spoken commands are entered using a microphone (22) received by an analogue to digital processing unit (28). USE/ADVANTAGE - Provides non contact operation using spoken commands. Used for medical applications.

Description

Diagnostic ultrasound device with an acoustic operator unit.

The invention relates to a diagnostic ultrasound device with an operating unit, about the operating states of the Ultrasound device can be specified manually and from the predetermined operating states operating state signals he testifies, and with one connected to the control unit Control system based on the operating status signals generated signals for the ultrasonic signal.

The screen representation of parts of the anatomy of the human body with the help of ultrasound is for medical diagnostics have become indispensable. Slide Gnostic ultrasound devices offer a variety of examination options, which depend on the medical Question through different operating states are characterized. In addition, different Para meters can be set on the device to get an optimal picture get representation. The operating states include also different types of image display such. B. A-, B-, M-mode and combinations thereof. For specifying the parameters or operating status is with commercial ultrasound devices an operating unit is provided, the z. B. a buttons field or includes a console. Special subs such as the studies of the lower extremities would be through a wireless or via a cable remote control of the operating states connected to the device facilitated. The remote control z. B. the picture  position, the field size and magnification, the activation control of a video printer or image storage control bar. To make work even easier, especially at a foot switch is provided for difficult examinations, the z. B. includes two pedals. Here is z. B. with the first Pedal of the image memory can be activated while the function of second pedal is freely selectable.

Diagnostic ultrasound devices are now also becoming increasingly popular for imaging of interventional (e.g. punctures) and invasive (e.g. surgical procedures) procedures puts. The problem exists with intraoperative use in that the device is usually not sterile, so that operation by another, in the non-sterile area stopping person must be taken over. With intraluminal The examiner usually has ultrasound examinations no more free hand to operate the ultrasound device. A The situation is similar with ultrasound-guided implantation radioactive seeds for the treatment of the prostate given cancer. As a rule, here the range from the Foot switch given options to select operating modes do not choose.

The invention is based on the object of an ultra to specify the sound device, the operating states of one Users can be specified without contact.

The object is achieved in that an acoustic operator unit is connected to the control system, which consists of acoustic Signals next to the control unit operating status signals testifies. The control of the operating states via acoustics control unit allows the examiner to concentrate fully on the  Focus investigation without operating the Ultrasound device to be distracted. He can also at difficult examination steps or ultrasound-guided Interventions use both hands and at the same time the Be driving state of the Ultra used in the investigation change the sound device. Ultrasound devices with acoustics Accordingly, service is used particularly in the Surgery, when examined with an ultrasound catheter and for ultrasound-guided implantation or Biopsy application.

An advantageous embodiment is characterized by that the acoustic control unit has a command memory Storage space for a maximum of 30 different data records comprises, wherein a data set an acoustic signal re presents. By limiting it to a relatively small one Number of acoustically clearly distinguishable signals or Commands result in a high level of accuracy in the Signal detection and thus a high level of security when loading Operation of the ultrasound device.

Another advantageous embodiment stands out by saying that the acoustic control unit has a voice synthesizer includes the acousti recognized as a command signals are linguistically confirmed. The language too Confirmation is used for operational security.

Another advantageous embodiment stands out by out that the acoustic control is a wireless micro phon includes. So the user is opposite a Ka not connected in its freedom of movement limits.

Two embodiments of the invention are as follows explained with reference to 2 figures. Show it

Fig. 1 is an acoustic control unit, which is connected via an interface to an ultrasound device and

Fig. 2 an Akustikbe control unit integrated in an ultrasound device with a wireless microphone.

The acoustic control unit controls a conventional ultrasound device 2 . The ultrasound device 2 is shown in Fig. 1 as a block diagram. The ultrasound device 2 comprises an ultrasound applicator 4 , which is connected to a transceiver unit 6 . The transceiver 6 generates transmission pulses which are emitted by the ultrasound applicator 4 as an ultrasound wave in an examination area. Echo signals received from the area under investigation are converted into electrical signals by the ultrasound applicator 4 and processed further by the transceiver unit 6 . The transceiver unit 6 is connected to a signal processing unit 8 , which generates image signals from the received echo signals, which are provided for display on a monitor 10 . Via an operating unit 12 which, for. B. a console with a keypad, function switches and adjustment controls for z. B. includes a depth-dependent gain, operating states of the ultrasound device 2 can be specified manually. The operating unit 12 generates operating state signals from the specified operating states. These operating state signals are entered as input signals into a controller 14 connected to the operating unit 12 . The controller 14 generates control signals from the operating state signals, which act on the transceiver 6 , the signal processing unit 8 and the monitor 10 . The control unit 12 can also include an infrared remote control, not shown here, with which the ultrasonic device 2 selected operating states can be specified. In addition, it is possible to specify one or two operating states via foot switches, also not shown, parallel to the operating unit 12 .

Important settings for the ultrasound device 2 , which can be made manually via the control unit 12 , are, for. B .:

• - Slider, the gain for different depths a depth compensation amplifier, the Settings saved for different applicator types can be
• - echo filter and image correlation in several stages,
• - dynamic range can be specified,
• - gray scale compression,
• - Image display type, e.g. B. A, B, M mode and combination,
• - line density specification,
• - enlargement of a predefinable picture window,
• - Selection of the time axis in M-mode display,
• - image reversal right / left or top / bottom,
• - image position,
• - black and white reversal for negative representation,
• - Save Image
• - etc.

Via an acoustic control unit 20 , selected operating states can now be specified without contact via acoustic signals. The acoustic control unit 20 comprises a microphone 22 , which is connected to the input of an adjustable threshold amplifier 24 .

The threshold value of the threshold amplifier 24 can be adjusted via a potentiometer 26 and is used to suppress background noise. The suppression of background noise can also be performed by a suitable circuit which uses a low-pass filter with a long time constant (up to several seconds) to form the mean value of the noise. This average then forms the threshold. The signal recorded by the microphone 22 must therefore have a minimum level in order to be further processed. A signal adaptation unit 28 is connected to the output of the amplifier 24 and converts characteristic properties of the analog acoustic signal into digital information for a microprocessor 30 . The function of the signal adaptation unit 28 will be explained further below.

Control elements 32 are connected to the microprocessor 30 , with which the various operating states of the acoustic control unit 20 can be predetermined. The main operating states of the acoustic control unit 20 are "learn commands" and "recognize commands". Display elements 34 are provided to inform the user of the operating states of the acoustic control unit 20 . Furthermore, a command memory 36 is connected to the microprocessor 30 , which is designed as a read-write memory and can store one or more user-specific command sets. Depending on the system used, z. B. a hard disk or a nonvolatile RAM card as a non-volatile command memory 36 in Be. A speech synthesizer 38 , also connected to the microprocessor 30 , serves to acoustically confirm a recognized command.

The detected by the microprocessor 30 commands are transferred as operating status signals via an interface 40 to the ultrasonic device 2, to which an interface 42 is provided in the ultrasonic unit 2 which passes the acquired command to the controller fourteenth

The procedure for recognizing the Acoustic signals as commands required compared to other methods a very low hardware and software expenditure. However, with this speech recognition process restrictive that only a few and acoustically well below separable words or commands can be recognized.

It is sufficient to limit the control of the ultrasound device 2 to a maximum of 30 operating states, that is to say 30 different commands. Selected operating states are e.g. B .:

• - Save Image
• - Real time
• - Ultrasound frequency 1
• - Ultrasound frequency 2
• - Enlarge area 1
• - Enlarge area 2
• - Enlarge area 3
• - Enlarge end
• - Hard copy for the depth compensation amplifier
• - Increase gain
• - decrease gain
• - scanning depth 1
• - scanning depth 2
• - scanning depth 3
• - Stop gain change.

The commands can be freely programmed by the user. If an attempt is made to enter two commands that are difficult to distinguish, the second command is rejected by the microprocessor 30 of the acoustic control unit 20 for security reasons.

Here, signal adaptation unit 28 evaluates the acoustic signal received by the microphone only after the zero crossings and not according to its amplitude. This eliminates agile amplitude normalization of the acoustic signal. The time between two zero crossings corresponds to the frequency. It is determined and encoded as a binary number. Here it is intended to take one word for each command, which is divided into 16 sections. This means that the same amount of data is obtained for each word. Each section is frequency-analyzed on its own. Due to the division into 16 sections of the same duration, it does not matter if a word is spoken at a different speed than in the saved version. In order to arrive at a sequence of numbers for each section that is relatively easy to compare with a reference pattern with a small memory requirement, the frequencies of the occurring frequencies are examined for each section. So it is only saved for each section, how often z. B. the frequency range 2 to 3.5 kHz appears. By limiting to a total of seven frequency ranges, a memory requirement of z. B. 7 × 8 bits. The eighth frequency range is not used, so 128 watts are saved per word.

The acoustic control unit 20 is thus able to save a command in the form of a frequency frequency pattern. Since slight differences occur every time the same word is spoken, each word is defined in a learning phase by the operating elements 32 . B. entered four times and an average pattern is stored as a record representing the acoustic signal.

In the “recognize command” operating mode, a word or command spoken into the microphone 22 is broken down into its frequency-frequency pattern and compared with all reference data sets. The command with the lowest sum of squares is recognized as an upper limit value can be set for the sum of squares.

In the ultrasound device 2 of FIG. 2, an Akustikbe control unit is inte grated in the control of the ultrasound device. A central controller 50 includes both the controller for the ultrasound device and the controller for the acoustic control unit. In comparison with the embodiment according to FIG. 1, the control 14 for the ultrasound device and the microprocessor 30 for the acoustic control unit are thus combined in the central control 50 . This also eliminates the interfaces 40 and 42 . In order not to hinder the user through cable connections, a wireless microphone 52 is provided, which in addition to the actual microphone 22 , for. B. a neck or larynx microphone, a microphone transmitter 54 includes. A microphone receiver 56 is arranged on the ultrasound device 2 and connected to the amplifier 24 . The rest of the functional units correspond to the units already described with reference to FIG. 1, the operating state of the acoustic control unit 20 being displayed via the monitor 10 .

The security when operating the ultrasound device can be increased by a so-called decision tree. It is checked based on the current operating state whether the recognized command is meaningful and harmless in this context. Additional security can be provided by an affirmative query e.g. B. can be achieved by the speech synthesizer 38 , which repeats the recognized command and a security question "are you sure?" or something like that. The command is then executed after a recognized confirmation with "yes" or a keyword defined by the user.

Claims (5)

1. The ultrasonic diagnostic apparatus (2) with a Bedienein unit (12) is manually presettable about the operating states of the ultrasonic device (2) and generates the operating states of the predetermined Be operating condition signals, and means connected to the control unit (12) controlling (14, 50 ), which generates control signals for the ultrasound device ( 2 ) from the operating state signals, characterized in that an acoustic control unit ( 20 ) is connected to the controller ( 14 , 50 ), which operating state signals from acoustic signals in addition to the operating unit ( 12 ) generated. 2. Diagnostic ultrasound device according to claim 1, characterized in that the acoustic control unit ( 20 ) is out as a voice control unit. 3. Diagnostic ultrasound device according to claim 1 or 2, characterized in that the acoustic control unit ( 20 ) comprises a command memory ( 36 ) with memory areas for at most 30 different data records, wherein a data record represents an acoustic signal or command. 4. Diagnostic ultrasound device according to one of claims 1 to 3, characterized in that the acoustic control unit ( 20 ) comprises a speech synthesizer ( 38 ) which actuates the acoustic signal recognized as a command by voice. 5. Diagnostic ultrasound device according to one of claims 1 to 4, characterized in that the acoustic control unit ( 20 ) comprises a wireless microphone ( 52 ).