KR20140143125A - Ultrasound Probe Being Controllable with Smartphone - Google Patents

Abstract

The present invention relates to an ultrasound probe capable of being controlled by a smart phone and, more particularly, to an ultrasound probe capable of processing an image in the smart phone from a signal transmitted from the ultrasound probe or operating the ultrasound probe by installing a unit to communicate with the smart phone. The ultrasound probe capable of being controlled by the smart phone includes a transducer which receives a reflected wave reflected by transmitting an ultrasound wave to a preset position in the human body, and a communications control module which communicates with the smart phone.

Description

[0001] Ultrasound probe capable of being controlled by a smart phone [0001]

The present invention relates to an ultrasound probe capable of being controlled by a smart phone, and more particularly, to an ultrasound probe capable of communicating with a smart phone and capable of operating an ultrasound probe or processing an image in a smart phone from a signal transmitted from the ultrasound probe, .

The ultrasonic diagnostic apparatus refers to a device for transmitting an ultrasonic wave having a frequency of 1 MHz or more into a human body to form an image of a specific region in the human body from a reflected wave. The ultrasound therapy apparatus refers to a device that transfers high intensity focused ultrasound to a specific site in the body to treat the patient by applying heat damage. Such an ultrasonic diagnostic or therapeutic apparatus may comprise a transducer or a probe for generating or receiving an ultrasonic pulse, an ultrasonic image signal processor for processing a signal transmitted from the probe, and a display device for outputting an image transmitted from the ultrasonic image signal processor have.

4 (a) and 4 (b) schematically show an external structure and an internal connection structure of a known ultrasonic diagnostic apparatus.

4A, a known ultrasound diagnostic apparatus includes a main body 41 having an apparatus such as an ultrasound image signal processor for processing an image, and a probe (not shown) An input device 43 for inputting control and management information of the apparatus, and a display device 44 for outputting an image processed in the main body 41. [ As shown in the right side of FIG. 4 (a), the ultrasonic diagnostic apparatus can be made into a movable form if necessary. The ultrasonic diagnostic apparatus of the moving type includes a main body 41 in the form of a box as in the standard device, a probe connector 42 provided on the side of the main body 41, an input device 43 provided on the upper surface of the main body 41, And a display device 44 for outputting the processed image in the main body 41. [ In the case of the moving mode, the display device 44 may be provided so as to have a lid function of the main body 41 so as to have a shape similar to that of the notebook as a whole. The internal structure of such an ultrasonic probe diagnostic apparatus is shown in FIG. 4 (B).

4 (b), the ultrasonic diagnostic apparatus includes a probe 45 (see FIG. 4) composed of a plurality of transducer elements 45A to 45N that generate ultrasonic waves and transmit the ultrasonic waves to the inside of the body, A transmission / reception (T / R) switch for switching the transmission and reception of ultrasonic waves in the course of operation of the probe 45, a transmission beam former 46 for generating an electric signal for beam forming of the transmission ultrasonic wave, A transmitter amplifier 46a for amplifying the signal of the shaping unit, a receiving amplifier 47a for amplifying the signal received from the probe 45, an analog-to-digital converter 47b for converting the signal transmitted from the receiving amplifier 47a, A receiving beam former 47 for forming a beam of focused form necessary for image formation from the converted digital signal, a video mode signal processor 48 for forming an image according to the signal transmitted from the receiving beam former 47, And a display device 44 for outputting an image transferred from the scan converter 49 and a scan converter 49 for converting the image signal transferred from the image mode signal processor 48 into a form suitable for display. The image mode signal processor 48 processes the transmitted signal into a B-mode corresponding to a two-dimensional image, processes it as a color flow image, or processes the signal in a Doppler spectrum, . A program for controlling the system can be installed in the main body 41 and information necessary for data management and control commands necessary for each device can be inputted through the input device 43. [ The power supply device is installed in the main body 41 so that power required for driving the device can be supplied from the outside. In addition, a storage device and an external device connection device may be installed if necessary.

Known apparatuses for ultrasonic diagnosis include a probe for transmitting and receiving ultrasonic waves and a body for processing a received signal, so that the apparatus main body can control only the operation of a predetermined probe. On the other hand, in order to operate the probe, the probe must be connected to the main body, and the main body can not perform other functions without the probe. Because of this, even if the probe becomes a potable structure, mobility can be restricted because the probe can operate only with the main body.

The present invention has been made to solve the above-described problems of the ultrasonic probe, and has the following purpose.

It is an object of the present invention to provide an ultrasonic probe which can be connected to a smart phone and controlled by a smart phone capable of image processing of a received signal.

It is another object of the present invention to provide an ultrasonic probe capable of being controlled by a smartphone which can be connected to a smartphone at any place in a movable form and can be diagnosed.

According to a preferred embodiment of the present invention, an ultrasonic probe capable of being controlled by a smart phone includes a transducer capable of receiving reflected waves reflected from ultrasonic waves transmitted to a predetermined position in the human body, and a communication control module capable of communicating with a smartphone do.

According to another preferred embodiment of the present invention, the ultrasonic probe further comprises a scan converter.

According to another preferred embodiment of the present invention, the communication control module communicates with the smartphone by wire or wirelessly.

According to another preferred embodiment of the present invention, the ultrasonic probe is portable.

According to another preferred embodiment of the present invention, the communication control module includes an external device recognition unit and a signal conversion unit.

According to another preferred embodiment of the present invention, the transducer comprises a separately installed transmit transducer and a receive transducer.

The probe according to the present invention does not require a separate input device for operating the probe and a separate ultrasound image signal processor for processing a signal received from the probe, thus making it possible to simplify the ultrasound diagnostic apparatus as a whole. Further, when the probe according to the present invention is made in a movable form, the probe can be diagnosed at an arbitrary place. In particular, when the probe is made portable, it can be used in connection with any smartphone, so that the ultrasonic diagnosis can be used without space or time limitation.

Figs. 1A, 1B and 1C are schematic block diagrams showing the configuration of a probe capable of being controlled by a smartphone according to the present invention.
FIG. 2A illustrates an embodiment of a communication control module 15, and FIG. 2B illustrates an embodiment of a method by which a probe is controlled by a smartphone by a communication control module.
FIG. 3 shows an embodiment of a transducer installed in a probe according to the present invention.
4 (a) and 4 (b) schematically show an external structure and an internal connection structure of a known ultrasonic diagnostic apparatus.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

Figs. 1A, 1B and 1C are schematic block diagrams showing the configuration of a probe capable of being controlled by a smartphone according to the present invention.

1A, the probe 10 includes a transducer 11 capable of generating and receiving ultrasonic waves, a mode switch 12 for determining the transmission and reception modes of the transducer 11, a transducer 11 To a receiving beamformer 14 which concentrates the received signal in a transducer 11 which converts the received mechanical signal into an electrical signal and which is connected to a smartphone 16 And a communication control module 15 that enables transmission and reception of data.

The transducer 11 may be of any shape capable of generating ultrasonic waves composed of a plurality of piezoelectric elements, and the present invention is not limited by the structure of the transducer 11, the generation or reception structure of the ultrasonic waves. The mode switch 12 may be provided to determine whether the transducer 11 should be in a transmit mode or a receive mode. Another function of the mode switch 12 is to convey to the communication control module 15 in which mode the transducer 11 is currently in the mode. If the transducer 11 has a structure in which the transmitting transducer and the receiving transducer are physically separated from each other, the mode switch 12 separates signals transmitted from the respective transducers and transmits them to the communication control module 15 And the like. The structure of the transducer will be described below again.

The transmission beam former 13 generates an electric signal for generating ultrasonic waves and transmits the ultrasonic waves to the transducer 11. The ultrasonic waves are focused on a desired portion according to an electrical signal generated. The generated ultrasonic waves are transmitted into the human body and received in the form of a reflected wave again at the transducer 11 to generate mechanical vibration. The mechanical vibration can be converted into an electrical signal and transmitted to the reception beam former 14. The transmission beamformer 13 and the reception beamformer 14 may be connected to the communication control module 15. The communication control module 15 may process an electric signal generated in the transmission beamformer 13 and a signal transmitted from the reception beamformer 14. [

The communication control module 15 is connected to the smartphone 16 to enable transmission and reception of data from the probe 10 to the smartphone 16. The communication control module 15 may be connected to the smartphone 16 by wire or wirelessly and the smartphone 16 may recognize the probe 10 as an external device through the communication control module 15. [ The communication control module 15 receives data related to the control of the probe 10 transmitted from the smartphone while transmitting data to the smartphone 16 and controls the operation of the probe 10 accordingly.

According to the configuration of the communication control module 15, devices and functions to be installed in the probe 10 and functions to be executed in the smartphone 16 can be determined.

FIG. 1B shows an embodiment of various devices to be installed in the probe 10 and various functions to be executed in the smartphone 16. FIG.

1B, the probe 10 includes a transducer 11, a transmission amplifier 131 for amplifying a transmission signal, a transmission beam generator 132 for generating an electrical signal, a reception amplifier (not shown) for amplifying a reception signal An A / D converter 143 for converting the received analog signal into a digital signal, a reception beam former 144 for focusing the reception beam at a desired position from the received signal, a signal of the reception beam former 144 Mode image device 171 for forming a two-dimensional image from the received signal, a tincture imaging device 172 for displaying blood flow or tissue motion in tones from the received signal, a Doppler imaging device 173 A scan converter 18 for converting the signals transmitted from the image devices 171, 172 and 173 into signals that can be displayed on a monitor for display, and a signal supplied from the scan converter 18 to the smartphone 16, U It may be made of a communication transmission control module 15 to. The B-mode image device 171, the tone image device 172, the Doppler imaging device 173 and the scan converter 18 become scanners and images formed in the scanner can be displayed on the display device. The smartphone 16 may have the functions of the monitor 161, the system control 162 and the power supply 163 if the probe 10 is made up of the device shown above. The communication control module 15 transmits the image data transmitted from the scan converter 18 to the smartphone 16 and the signal transmitted to the smartphone 16 can be displayed on the screen. On the other hand, the smartphone 16 controls the transmission of data related to the operation of the probe 10 and the processing of the image. Specifically, the system control 162 of the smartphone has functions of controlling the components of the probe 10, inputting control commands, storing information related to the transmitted images, and recognizing external devices. The smartphone 16 also has the function of a power supply 163 that supplies the power required for operation of the probe 10.

In the embodiment shown in FIG. 1B, the functions related to the processing of the image are installed in the probe 10, but the functions related to the processing of the image may be executed by the smartphone 16 if necessary. The function of the communication control module 15 and the data transmission method according to the functions executed in the smartphone 16 may be changed.

1C, the probe 10 includes an image forming device (not shown) such as a transducer 11, a transmit beamformer 13, a receive beamformer 14, a B-mode image device, a tone image device, 17 and a scan converter 18 and the smartphone 16 may include a monitor 161, a system control 162, an image processing device 17a and a power supply 163. The monitor 161, The image forming apparatus 17 and the scan converter 18 provided in the probe 10 are provided with a sampling circuit for converting signals according to a plurality of scan lines transferred from the transducer into a digital signal while arranging them in a predetermined form, And the like. The thus converted digital signal can not be directly transmitted to the smartphone 16. A signal related to the image converted into the digital signal and stored in the temporary storage device can be transmitted to the smartphone through the communication control module described above. On the other hand, the image processing apparatus 17a installed in the smartphone 16 is a device for converting a signal related to the image transferred through the communication control module into a signal form that can be displayed on the smartphone 16. [ Such an apparatus is an apparatus or a program that can be connected to an application program for displaying an image installed in the smartphone 16 or converts a signal related to the image in a manner that can be expressed in an application program. Therefore, the image processing apparatus 17a may depend on the type of data to be converted by the communication control module.

The manner in which the image is represented may be determined by the communication control module.

An embodiment of a communication control module and a method of connecting a probe and a smartphone by a communication control module will be described below.

FIG. 2A illustrates an embodiment of a communication control module 15, and FIG. 2B illustrates an embodiment of a method by which a probe is controlled by a smartphone by a communication control module.

2A, the communication control module 15 includes a data arrangement unit 151 for storing an image transmitted from the probe 10 in a predetermined manner, a probe 10 for recognizing the probe 10 as an external peripheral device An input unit generating unit 153 for enabling an input of a command to the probe and an external device recognizing unit 152 for converting a signal stored in the data array unit 151 into a signal that can be processed in the smartphone 16 And a signal conversion unit 154 for transmitting the signal.

The data array unit 151 has a function of assigning an identifier to a signal transmitted from the scan converter 18 of the probe and storing the identifier. The data array unit 151 may be in the form of a random access memory or a flash memory and the stored data may have an identifier according to the transmitted time. The external device recognition unit 153 allows the smartphone 16 to be recognized as an external device when the probe 10 is connected to the smartphone 16. [ Recognition of an external device refers to, for example, a device that can be controlled by a smart phone, such as a scanner, which is connected to an external connector and can be synchronized to enable transmission and reception of related data. The probe 10 according to the present invention may be connected to the smartphone 16 either wired or wirelessly. The external device recognizing unit 152 allows the smart phone 16 to be recognized as an external device capable of transmitting data. For example, the external device recognizing unit 153 may be recognized by the smartphone 16 as a virtual camera or a virtual scanner. Alternatively, the external device recognition unit 152 may allow the probe 10 to be connected to the smartphone 16 via the Internet. As described above, the external device recognizing unit 153 has a function of allowing the probe 10 to access the smartphone 16 and transmit data. On the other hand, if the probe 10 is wirelessly connected to the smartphone 16, the external device recognition unit 152 may be configured to wirelessly connect the probe 10 to the smartphone 16 in a wireless (wifi) can do. For this purpose, for example, the external device recognition unit 152 may include a wireless access point. As described above, the external device recognizing unit 152 may take various forms according to a connection mode or a data transmission mode, and the present invention is not limited to a specific mode for transmitting and receiving data.

The input means generating unit 153 has a function of causing the smartphone 16 to generate a command inputting means for enabling the control of the probe 10 by the smartphone 16. [ The input means creation unit 153 may, for example, cause a virtual keyboard to be created on the screen of the smartphone 16. [ Alternatively, the input means generation unit 153 may have a function of converting a specific key of the smartphone 16 to be a command instructing a specific operation of the probe 10. [ The input means generating unit 153 allows the smartphone 16 to recognize the probe 10 by the operation of the external device recognizing unit 152 and simultaneously input the recognized device to the smartphone 16 . The control means for the probe 10 generated in the smartphone 16 may be a command input key installed in the smartphone 10 and a separate operation screen may be generated if necessary.

The signal conversion unit 154 functions to convert a signal transmitted for the generation of an image in the probe 10 into the form of a signal that can be expressed in the smartphone 16. The manner of the data converted by the signal conversion unit 154 depends on the type of the device that recognizes the probe 10 in the smartphone 16 by the external device recognition unit 152. [ If the probe 10 and the smartphone 16 are connected wirelessly, the method of data may follow the communication protocol defined for the Wi-Fi.

The embodiment shown in FIG. 2A is exemplary and the communication control module 15 may include various units for converting the image signals processed in the probe 10 into an appropriate data format and delivering it to the smartphone 16. And may include a unit for controlling the required operation of the probe 10 in the smartphone 16. [ In addition, such units may be suitably integrated into a single chip or programmed. Therefore, the present invention is not limited to the embodiments shown.

Although not shown in FIG. 2A, the communication control module can control the power supplied from the smartphone 16 to the probe 16 when the probe 10 is connected to the smartphone 16 by wire. The power supply line may be installed in a cable for data transmission or may be installed separately. However, the probe 10 may have its own power supply means.

FIG. 2B is a schematic view showing an embodiment of a process in which an image signal received from a probe is processed in a smartphone according to the present invention.

Referring to FIG. 2B, the probe may be connected to the smartphone by wire or wirelessly by the communication control module (S11). When the connection to the smartphone is confirmed, the operation of the probe is started (S12). Simultaneously with the connection to the smartphone, the communication control module activates an external device recognition unit to determine the type of device the probe recognizes on the smartphone and synchronize the probe and the smartphone. Then, the operation mode is determined (S13). The operating mode is to determine whether the operation of the probe will be controlled by a switch installed in the probe or controlled by a smart phone. If it is controlled by a smart phone, the communication control module activates the input means creating unit to create the input means on the smart phone. Otherwise, the communication control module maintains only the connection state if it operates on the probe. If necessary, the position in the body where the ultrasonic waves are transmitted from the probe can be transmitted to the screen to be confirmed on the smartphone. For example, a probe generates a pulse, transmits it to the human body, processes the reflected wave, and transmits it to the smartphone to confirm in advance the location to be diagnosed.

When the operation of the probe is started (S12) and the ultrasonic wave is transmitted to the predetermined position in the human body and the reflected wave is again received at the probe (S14), the signal is transmitted by the B-mode image device, the tint image device or the Doppler image device And converted into a digital signal (S15). The converted signal may be transmitted directly to the smart phone or may be preprocessed in the probe and transmitted to the smart phone. The communication control module determines whether direct transmission is possible (S16). If the scan converter is not installed in the probe and the data format to be processed by the communication control module is determined in advance (YES), the received signal is converted into the data format to be transmitted in the probe (S18) And transmitted to the smartphone directly by wire or wireless through the control of the control module. Otherwise, if the scan converter is installed in the probe and the image signal should be processed in a predetermined data format (NO), the image is processed first by the scan converter (S17). Then, a data format that can be transmitted and processed by the smart phone is determined for the processed image (S18). When the data format is determined, the communication control module performs data conversion according to the data format and transmits the data to the smart phone (S19). The data transmitted to the smartphone can be displayed on the screen and the diagnosis can be made accordingly.

If the probe is connected to the smartphone and the final image is displayed on the smartphone, a favorable condition for diagnosis may be created. For example, it has the advantage that the final image can be transferred to the smartphone and transferred to another place as an e-mail. It is also possible that the image displayed on the smartphone is compared with other images retrieved through the smartphone. It also has the advantage that various diagnostic applications can be downloaded and installed on the smartphone and used for the operation and diagnosis of the probe.

As such, when the probe is controlled by a smartphone, the various advantages of the smartphone have the advantage that they can be directly used for operation, image processing or diagnosis of the probe.

Hereinafter, an embodiment of a transducer installed in a probe that can be connected to a smart phone and an image forming method therefor will be described below.

FIG. 3 shows an embodiment of a transducer installed in a probe according to the present invention.

Referring to FIG. 3A, the transducer may include a transmitting transducer 31 for generating ultrasonic waves and receiving transducers 32a and 32b for receiving ultrasonic waves reflected from the inside of the human body. The transmitting transducer 31 may be installed at an intermediate portion and the receiving transducers 32a and 32b may be installed symmetrically or asymmetrically on both sides. Referring to FIG. 3 (B), the transmitting transducer 31 and the receiving transducer 32 may be installed in parallel. Referring to FIG. 3 (C), the transmitting transducer 31 may be installed at the center, and the receiving transducers 32a, 32b, 32c and 32d may be installed around the receiving transducer. The positions of the transmitting transducer 31 and the receiving transducers 32a, 32b, 32c, and 32d may be mutually changed. In addition, the transmitting transducer and the receiving transducer may not be distinguished, if necessary. In other words, a reflected wave can be received from a transducer that generates and transmits ultrasonic waves.

Harmonics can be received to form an image from the reflected wave. The formation of images using harmonics is known as harmonic imaging in this field. The probe according to the present invention can form an image according to various harmonic imaging methods.

It should be appreciated that the structure of the transducer shown in FIG. 3 is exemplary and as already described above, the probe according to the present invention may have any transducer structure known in the art and is not limited to the embodiments shown.

The probe according to the present invention does not necessarily have to be made portable. However, the standard type device or the mobile type device not associated with a smart phone has a separate image processing and display device, and has a disadvantage that it is not portable or weak. In contrast, the probe according to the present invention has an advantage that portability can be improved.

It is advantageous that the structure of the probe itself is simplified in order to improve portability in the probe according to the present invention. Therefore, even when an image is formed according to the harmonic imaging method, it is advantageous that the structure for generating, transmitting, and accordingly receiving reflected waves is simplified.

In order to form an image according to the harmonic imaging method in the probe according to the present invention, the receiving probe may have a symmetrical structure. Symmetrical structure means physically symmetrical and acoustically symmetrical structure. And the acoustically symmetric structure means that, for example, two receiving transducers installed at different positions receive reflected waves having the same phase.

In the embodiment shown in Fig. 3 (a), two transducers 32a and 32b are installed at symmetrical positions and a reflected wave having the same phase can be received. The phase inversion can be performed for any one of the reflected waves received from the transducers 32a and 32b. The phase inversion is to change the phase as much as the half-wavelength of the received reflected wave phase. When the reflected waves received from the two transducers 32a and 32b are synthesized, the fundamental waves cancel each other and only harmonics can overlap with each other. When an image is formed by processing the reflected wave, the process of removing the fundamental frequency from the reflected wave separately in the harmonic image method can be avoided. It is also possible to simplify the structure of the entire probe by eliminating the need for a separate filter device for removing the fundamental frequency.

Since the probe according to the present invention does not require a separate input device for operating the probe and a separate image processing device for processing a signal received from the probe, it is advantageous in that the device for ultrasound diagnosis is simplified as a whole . Further, when the probe according to the present invention is made in a movable form, the probe can be diagnosed at an arbitrary place. In particular, when the probe is made portable, it can be used in connection with any smartphone, so that the ultrasonic diagnosis can be used without space or time limitation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, . The invention is not limited by these variations and modifications, but is only limited by the scope of the appended claims.

10: probe 11: transducer
12: Mode switch 13: Transmission beam former
14: Receive beamformer 15: Communication control module
16: smartphone 17: image forming device
18: Scan converter
131: transmission amplifier 132: transmission beam generator
142: receiving amplifier 143: A / D converter
144: Receive beamformer 151: Data array unit
152: External device recognizing unit 153: Input unit generating unit
154: Signal conversion unit 171: B-mode image device
172: Tint imaging device 173: Doppler imaging device
17a: Image processing device
41: main body 42: probe connector
43: input device 44: display device
45: probes 45A to 45N: transducer
46: transmit beam former 46a: transmit amplifier
47: reception beam former 47a: reception amplifier
47b: analog-to-digital converter 48: video mode signal processor
49: scan converter
SW: Switch T / R: Transmit / Receive switch

Claims (2)

A transducer 11 capable of receiving a reflected wave reflected from an ultrasonic wave transmitted to a predetermined position in a human body, a mode switch 12 for determining a transmission and reception mode of the transducer 11, The mode switch 12 includes a communication control module 15 capable of controlling the current of the transducer 11 and the signal transmitted from the transducer 11 is processed in a sampling circuit and stored in a temporary storage device, The signal stored in the temporary storage device is processed according to the control of the smartphone and the signal transmitted from the image device is processed in the scan converter 18 to be transmitted to the communication control module 15 15. The ultrasonic probe according to claim 1, wherein the function of the smartphone is determined according to the configuration of the communication control module (15).  The transducer according to claim 1, wherein the transducer (31) comprises a transmitting transducer (31) and receiving trend ducers (32a, 32b), and the receiving transducers (32a, 32b) The ultrasonic probe being capable of being controlled by a smartphone.

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