KR101832024B1 - Ultrasound system, method and computer program for performing signal process on receive-focused signal - Google Patents

Abstract

The present invention relates to an ultrasound system, method and computer program for performing at least one of composite aperture processing and pulse compression processing on a receive focusing signal in accordance with pulse length information and composite aperture information. An ultrasound system according to the present invention includes: an ultrasound probe operable to transmit an ultrasound signal to a target object and receive an ultrasound echo signal reflected from the target object; A receive concentrator operative to form a receive focus signal based on an ultrasound echo signal; At least one of a first signal processing for forming a harmonic image signal of a harmonic image or a composite image signal of a synthesized aperture image and a second signal processing for forming a pulse compressed signal, according to pulse length information and composite aperture information A pulse compression unit operable to perform an ultrasound image signal on the focusing signal; And an image forming unit operable to form an ultrasound image based on the ultrasound image signal.

Description

Field of the Invention [0001] The present invention relates to an ultrasound system, a method, and a computer program for performing signal processing on a receive focusing signal,

The present invention relates to an ultrasound system, and more particularly, to an ultrasound system that performs at least one of a synthesizing aperture process and a pulse compression process on a reception focusing signal in accordance with a length of a pulse signal (transmission signal or reception signal) and an ultrasound image to be formed, And a computer program.

Ultrasound systems have non-invasive and non-destructive properties and are widely used in the medical field to obtain information inside the living body. The ultrasound system is very important in the medical field because it can provide high-resolution images of the internal tissues of the living body in real time without the need of a surgical operation to directly observe the living body.

The ultrasound system includes an ultrasonic transducer including a plurality of transducers for transmitting an ultrasonic signal to a living body, and a pulser for supplying a pulse signal for driving each transducer. Each transducer generates an ultrasonic signal in response to a pulse signal applied from the pulsar. When the ultrasonic signal is transmitted, the transducers transmit and focus the ultrasonic signal to a predetermined position (focusing point) in the living body by adjusting the timing of generating the ultrasonic signal. An ultrasonic signal reflected from an object in the living body (i.e., an ultrasonic echo signal) is received at each transducer. Since the time at which the ultrasonic echo signal reaches each transducer differs depending on the position of each transducer, in order to compensate for the difference in arrival time, the beamformer transmits a time delay to the ultrasonic echo signal received through each transducer (Reception focusing signal) by adding and adding the signals.

On the other hand, when the ultrasonic signal passes through a medium having a strong attenuation such as a living tissue, the power of the ultrasonic echo signal received due to the attenuation is significantly reduced. This makes it difficult to obtain desired information when the depth of the ultrasound image to be formed (i.e., to be diagnosed) is deep. In order to increase the resolution of the ultrasonic signal in the axial direction (that is, in order to increase the resolution in the axial direction), a pulse signal having a very short duration and a high voltage is applied to the transducer to generate an ultrasonic signal, thereby attenuating the ultrasonic signal. However, in the ultrasound system, particularly the medical ultrasound system, the voltage used for generating the ultrasound signal is about -80 V to +80 V or about 0 V to 200 V. That is, the voltage used in the ultrasound system is within about 200 V , There is a limitation in increasing the voltage of the pulse signal while maintaining the durability of the ultrasonic system without affecting the tissue inside the living body.

A pulse compression method is a method that significantly improves the signal to noise ratio of an ultrasound system by increasing the average power instead of increasing the voltage of the pulse signal. An ultrasonic system using a pulse compression technique uses a long pulse signal (hereinafter referred to as a long pulse signal) coded in place of a conventional short pulse signal (hereinafter, referred to as a short pulse signal). This pulse compression technique forms a relatively low voltage pulse signal and increases the length of the pulse signal to increase the intensity of the entire ultrasonic signal to compensate the signal-to-noise ratio of the ultrasonic signal. When the received ultrasonic echo signal is subjected to appropriate signal processing The resolution in the axial direction can be increased as in the case of using a short pulse signal. There are Barker, Golay, and Chirp signals as signal codes with special properties that are known pulse compression so far.

Ultrasonic systems must implement special circuit devices to perform such pulse compression techniques. That is, the ultrasound system includes a memory for storing correlation coefficients for separating and pulse-compressing pulse signals, a correlator for performing pulse compression based on a correlation coefficient, a short pulse signal for receiving a short pulse signal, I need a switch. Such a circuit device for pulse compression must be implemented in all channels before performing receive focusing, thereby increasing the complexity and development cost of the ultrasound system.

On the other hand, the ultrasound system performs signal processing such as DC component removal, time gain compensation, and the like on the receive focusing signal, and then performs the synthesizing aperture processing. Accordingly, when there is a noise and an error component in the reception focusing signal, when the reception focusing signal having the noise and error components is amplified, not only the reception focusing signal but also the noise and error components are amplified so as to have a frequency corresponding to an integral multiple of the fundamental frequency There is a problem that the mood frequency components are not completely removed from the harmonic image of the harmonic (more preferably the second harmonic), or images of different diameters are not correctly synthesized in the synthesized aperture image.

The present invention provides an ultrasound system, method, and computer program that performs at least one of synthesizing aperture processing and pulse compression processing on a reception focusing signal in accordance with a length of a pulse signal (transmission signal or reception signal) and an ultrasound image to be formed .

According to an embodiment of the present invention, there is provided an ultrasound system including: an ultrasound probe operable to transmit an ultrasound signal to a target object and receive an ultrasound echo signal reflected from the target object; A receive focusing unit operable to form a receive focus signal based on the ultrasound echo signal; At least one of a first signal processing for forming a harmonic image signal of a harmonic image or a composite image signal of a synthesized aperture image and a second signal processing for forming a pulse compressed signal based on pulse length information and composite aperture information A pulse compression unit operable to form an ultrasound image signal on the receive focusing signal; And an image forming unit operable to form an ultrasound image based on the ultrasound image signal.

According to another aspect of the present invention, there is provided a method of performing signal processing on a receive focusing signal, the method comprising: receiving an ultrasonic echo signal transmitted from a target object; Forming a receive focusing signal based on the ultrasonic echo signal; At least one of a first signal processing for forming a harmonic image signal of a harmonic image or a composite image signal of a synthesized aperture image and a second signal processing for forming a pulse compressed signal in accordance with pulse length information and composite aperture information, Forming ultrasound image signals on the receive focusing signals; And forming an ultrasound image based on the ultrasound image signal.

According to another embodiment of the present invention, a computer program stored in a medium for causing a computer to execute a method of performing signal processing on a receive focusing signal includes a step of forming a receive focusing signal based on an ultrasonic echo signal reflected from the object step; At least one of a first signal processing for forming a synthesized aperture image signal of the harmonic image signal of the harmonic image or a synthesized aperture image and a second signal processing for forming the pulse compressed signal in accordance with the pulse length information and the synthesize aperture information Forming an ultrasound image signal on the receive focusing signal; And forming an ultrasound image based on the ultrasound image signal.

The present invention can reduce the complexity and development cost of the ultrasound system by providing the pulse compression unit at the rear stage of the reception focusing unit for performing the reception focusing process, compared with the conventional case where the pulse compression unit is provided for each of the plurality of channels.

In addition, the present invention can perform at least one of a synthesizing aperture process and a pulse compression process on a reception focusing signal provided from a reception focusing unit, considering a pulse length of a transmission signal (or a reception signal) and an ultrasound image to be formed .

Further, the present invention can minimize the distortion of the receive focusing signal by performing at least one of the composite aperture process and the pulse compression process before performing signal processing such as DC component removal, time gain compensation, and the like. Therefore, it is possible to completely remove the fundamental frequency component from the harmonic image of the harmonics (more preferably the second harmonic) having a frequency corresponding to an integer multiple of the fundamental frequency, as well as to accurately synthesize images of different diameters in the composite aperture image can do.

1 is a block diagram schematically showing a configuration of an ultrasound system according to an embodiment of the present invention.
2 is a block diagram schematically illustrating a configuration of a processor according to an embodiment of the present invention;
3 is a block diagram schematically showing a configuration of a pulse compression unit according to an embodiment of the present invention;
4 is a flowchart illustrating a procedure for forming an ultrasound image according to an embodiment of the present invention.
5 is a flowchart illustrating a procedure for forming an ultrasound image according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. The term "part " used in the present embodiment means hardware components such as software, field-programmable gate array (FPGA), and application specific integrated circuit (ASIC). However, "part" is not limited to software and hardware. "Part" may be configured to be stored in an addressable storage medium, and configured to play back one or more processors. Thus, by way of example, and not limitation, "part (s) " includes components such as software components, object- Microcode, circuitry, data, databases, data structures, tables, arrays, and variables. The functions provided within the component and the "part " may be combined into a smaller number of components and" parts " or further separated into additional components and "parts ".

1 is a block diagram schematically showing a configuration of an ultrasound system according to an embodiment of the present invention. Referring to FIG. 1, an ultrasound system 100 includes an ultrasound probe 110.

The ultrasonic probe 110 transmits an ultrasonic signal to a living body (not shown) and receives an ultrasonic signal (i.e., an ultrasonic echo signal) reflected from the living body. The ultrasound probe 110 includes an ultrasound transducer 112, which is operable to convert an electrical signal and an ultrasound signal into each other, as shown in FIG. The ultrasonic transducer 112 converts an electric signal into an ultrasonic signal, and transmits the ultrasonic signal to the living body. The ultrasonic transducer 112 receives an ultrasonic echo signal reflected from a living body and converts the received ultrasonic echo signal into an electrical signal (hereinafter referred to as a reception signal). The received signal is an analog signal. The ultrasonic probe 110 includes a convex probe, a linear probe, and the like.

The ultrasound system 100 further includes a processor 120. Processor 120 controls the transmission of ultrasonic signals. In addition, the processor 120 forms an electrical signal (hereinafter referred to as a transmission signal) for obtaining an ultrasound image, and transmits the formed transmission signal to the ultrasonic probe 110. In addition, the processor 120 performs signal processing on an ultrasonic echo signal (i.e., a received signal) transmitted from the ultrasonic probe 110 to form an ultrasonic image for a living body. The processor 120 includes a central processing unit (CPU), a graphics processing unit (GPU), a microprocessor, and the like. The processor 120 will be described in detail below.

The ultrasound system 100 further includes a control panel 130. The control panel 130 receives input information from a user and transmits the received input information to the processor 120. The input information includes pulse length information and composite aperture information.

In one embodiment, the pulse length information includes input information for selecting any one of the pulse signals having different lengths. As one example, the pulse length information includes input information for selecting a pulse signal (hereinafter referred to as a first pulse signal) having a high voltage and a short temporal length as a pulse signal (transmission signal or reception signal). As another example, the pulse length information includes input information for selecting a pulse signal (hereinafter, referred to as a second pulse signal) having a longer voltage and a lower voltage than the first pulse signal as a pulse signal (transmission signal or reception signal) do. The second pulse signal includes a Barker code, a Golay code, an orthogonal Golay code, a Chirp signal, a weighted chirp signal, and the like as pulse compressible code signals. The pulse length information further includes input information for selecting a pulse-compressible code signal.

In another embodiment, the composite aperture information includes input information for selecting an ultrasound image to be formed. As an example, the composite aperture information includes input information for selecting a basic ultrasound image of a fundamental frequency (hereinafter, referred to as a first ultrasound image) as an ultrasound image. As another example, the composite aperture information may include input information for selecting a harmonic harmonic image (hereinafter referred to as a second ultrasound image) having a frequency that is an integer multiple (more preferably, two times) of the fundamental frequency as an ultrasound image do. As another example, the composite aperture information includes input information for selecting a composite aperture image (hereinafter referred to as a third ultrasound image) obtained by synthesizing images of different aperture sizes as an ultrasound image.

The control panel 130 is provided with various input units for performing operations such as selection of a diagnostic mode, control of a diagnostic operation, input of a command necessary for diagnosis, signal operation, output control, and the like, As components, for example, an input unit such as a trackball, a keyboard, and a plurality of buttons is provided.

The ultrasound system 100 further includes an output unit 140. The output unit 140 outputs an ultrasound image formed by the processor 120. Also, the output unit 140 may output the input information input through the control panel 130. The output unit 140 includes a display unit, a speaker, and the like.

2 is a block diagram schematically illustrating the configuration of a processor 120 according to an embodiment of the present invention. Referring to FIG. 2, the processor 120 includes a transmitter 210. The transmitting unit 210 forms a transmission signal for obtaining an ultrasound image based on the input information provided from the control panel 130.

In one embodiment, the transmitter 210 forms a transmission signal corresponding to the first pulse signal (hereinafter, referred to as a first transmission signal) based on the pulse length information provided from the control panel 130. Accordingly, the ultrasonic transducer 112 converts the first transmission signal provided from the transmission unit 210 into an ultrasonic signal, transmits the ultrasonic signal to the living body, receives the ultrasonic echo signal reflected from the living body, Hereinafter, referred to as a first received signal).

In another embodiment, the transmitting unit 210 forms a transmission signal corresponding to the second pulse signal (hereinafter, referred to as a second transmission signal) based on the pulse length information provided from the control panel 130. Accordingly, the ultrasonic transducer 112 converts the second transmission signal provided from the transmission unit 210 into an ultrasonic signal, transmits the ultrasonic signal to the living body, receives the ultrasonic echo signal reflected from the living body, Hereinafter, referred to as a second received signal).

The transmission unit 210 includes a transmission focusing delay memory (not shown) for storing a delay pattern of an ultrasonic pulse for compensating a time for an ultrasonic signal to arrive at a target object according to the position of the ultrasonic transducer 112, And a pulse generator (not shown) for receiving the transmission signal pattern delayed in transmission from the transmission pattern memory and amplifying the received transmission signal pattern with a pulse having a voltage of a predetermined magnitude ).

The processor 120 further includes a transmit / receive switch 220. The transmission / reception switch 220 serves as a duplexer so that the high-voltage transmission signal emitted from the transmission unit 210 does not affect the reception unit 230 described later. That is, when the ultrasonic transducer 112 performs transmission and reception alternately, the transmission / reception switch 220 appropriately switches the transmission unit 210 and the reception unit 230 to the ultrasonic transducer 112.

The processor 120 further includes a receiving unit 230. [ The reception unit 230 converts a reception signal, which is a radio frequency (RF) signal provided from the ultrasonic transducer 112 through the transmission / reception switch 220, into a digital signal. The receiving unit 230 is connected to each of a plurality of channels (not shown).

In one embodiment, the receiver 230 generates a digital signal (hereinafter, referred to as a first digital signal) by analog-to-digital conversion of a first reception signal provided from the ultrasonic transducer 112 through the transmission / reception switch 220 do.

In another embodiment, the receiving unit 230 converts a second received signal provided from the ultrasonic transducer 112 through the transmitting / receiving switch 220 into a second digital signal (hereinafter, referred to as a second digital signal) .

The processor 120 further includes a receive-focusing unit 240. Based on a time delay value for compensating a time of arrival of an ultrasonic echo signal reflected from a subject of a living body in accordance with the position of the ultrasonic transducer 112, a digital signal provided from a plurality of channels (not shown) To form a receive focus signal.

In one embodiment, the receive-focusing unit 240 performs receive-focusing of the phase rotation type on the first digital signal provided from the receiving unit 230. That is, the receive-focusing unit 240 converts the first digital signal provided from the receiving unit 230 into an in-phase / quadrature (IQ) signal, performs focusing focusing on the converted IQ signal, (Hereinafter referred to as a first reception focusing signal).

In another embodiment, the receive-focusing unit 240 performs receive-focusing on a first digital signal provided from the receiving unit 230 after a delay. That is, the receive-focusing unit 240 forms a receive-focusing signal (hereinafter referred to as a second receive-focusing signal) by performing receive-focusing in a post-additive manner on the first received signal provided from the receiving unit 230.

In another embodiment, the receive-focusing unit 240 performs receive-focusing on the second digital signal provided from the receiving unit 230 in a phase rotation manner. That is, the receive-focusing unit 240 converts the second digital signal provided from the receiving unit 230 into an in-phase / quadrature (IQ) signal, performs a receive-focusing operation on the converted IQ signal, (Hereinafter, referred to as a third reception focusing signal).

In another embodiment, the receive-focusing unit 240 performs receive-focusing on the second digital signal provided from the receiving unit 230 after the add-delay method. That is, the receive-focusing unit 240 forms a receive-focusing signal (hereinafter, referred to as a fourth receive-focusing signal) by performing receive-focusing on a second received signal provided from the receiving unit 230,

The processor 120 further includes a pulse compressor 250. The pulse compression unit 250 performs a synthesis aperture process and a pulse generation process on the receive focusing signal provided from the receive focusing unit 240 in consideration of input information (i.e., pulse length information and composite aperture information) provided from the control panel 130. [ And a compression process. The pulse compression unit 250 will be described in more detail below.

The processor 120 further includes a signal processing unit 260. [ The signal processing unit 260 performs signal processing on the receive focusing signal provided from the pulse compressing unit 250 to form a receive focusing signal (hereinafter, referred to as an ultrasound image signal) Thereby forming an ultrasound image for the living body. The receive focusing signal provided from the pulse compressing unit 250 includes a composite receive signal, a composite receive beamformed signal, a pulse condensed receive receive signal, a composite aperture processed and pulse compressed receive receive focused signal, And a receive-focusing signal. In one embodiment, the signal processing unit 260 performs signal processing such as DC component removal, time gain compensation, envelope detection, log compression, and the like.

3 is a block diagram schematically showing the configuration of the pulse compression unit 250 according to the embodiment of the present invention. Referring to FIG. 3, the pulse compression unit 250 includes a first signal selector 310.

The first signal selector 310 analyzes input information (i.e., pulse length information and composite aperture information) provided from the control panel 130 and outputs a receive focusing signal (Not shown) for transmitting the received signal, and transmits the received signal through the selected transmission path.

In one embodiment, the first signal selector 310 analyzes pulse length information and composite aperture information provided from the control panel 130, and the pulse length information is input information for selecting the first pulse signal, And determines whether the information is input information for selecting the first ultrasound image. If it is determined that the pulse length information is the input information for selecting the first pulse signal and the composite aperture information is the input information for selecting the first ultrasound image, the first signal selector 310 may be provided from the receive focusing unit 240 (The first reception focusing signal or the second reception focusing signal) to the signal processing unit 260, and transmits the reception focusing signal to the signal processing unit 260 through the selected transmission path .

In another embodiment, the first signal selector 310 analyzes pulse length information and composite aperture information provided from the control panel 130, and the pulse length information is input information for selecting the first pulse signal, And determines whether the information is input information for selecting the second ultrasound image. When it is determined that the pulse length information is the input information for selecting the first pulse signal and the composite aperture information is the input information for selecting the second ultrasound image, the first signal selector 310 receives the pulse signal from the receive focusing unit 240 (The first reception focusing signal or the second reception focusing signal) to the composite aperture processing unit 320 to be described later, and outputs the reception focusing signal to the composite aperture processing unit 320 ).

In another embodiment, the first signal selector 310 analyzes pulse length information and composite aperture information provided from the control panel 130, and pulse length information is input information for selecting the first pulse signal, It is determined whether or not the aperture information is the input information for selecting the third ultrasound image. If it is determined that the pulse length information is input information for selecting the first pulse signal and that the synthesized aperture information is input information for selecting the third ultrasound image, the first signal selector 310 may be provided from the receive focusing unit 240 (The first reception focusing signal or the second reception focusing signal) to the composite aperture processing unit 320 and transmits the reception focusing signal to the composite aperture processing unit 320 through the selected transmission path send.

In another embodiment, the first signal selector 310 analyzes pulse length information and composite aperture information provided from the control panel 130, and the pulse length information is input information for selecting the second pulse signal, It is determined whether or not the aperture information is input information for selecting the first ultrasound image. If it is determined that the first input information is the input information for selecting the second pulse signal and the composite aperture information is the input information for selecting the first ultrasound image, the first signal selector 310 selects the second ultrasound image from the receive focusing unit 240 (A third receive focus signal or a fourth receive focus signal) to a second signal selector 330, which will be described later, and selects a receive focus signal through the selected transmit path as the second receive signal And transmits it to the signal selection unit 330.

In another embodiment, the first signal selector 310 analyzes pulse length information and composite aperture information provided from the control panel 130, and the pulse length information is input information for selecting the second pulse signal, It is determined whether or not the aperture information is input information for selecting the second ultrasound image. If it is determined that the first input information is the input information for selecting the second pulse signal and the composite aperture information is the input information for selecting the second ultrasound image, the first signal selector 310 selects the second ultrasound image from the receive focusing unit 240 (The third reception focusing signal or the fourth reception focusing signal) to the composite aperture processing unit 320, and outputs a reception focusing signal to the composite aperture processing unit 320 through the selected transmission path, Lt; / RTI >

In yet another embodiment, the first signal selector 310 analyzes the composite aperture information provided from the control panel 130 to determine whether composite aperture information is the input information for selecting the second ultrasound image. When it is determined that the composite aperture information is the input information for selecting the second ultrasound image, the first signal selector 310 selects the second ultrasound image based on the receive focusing signals (the first receive focusing signal to the fourth receive focus Signal to the composite aperture processing unit 320, and transmits the reception focusing signal to the composite aperture processing unit 320 through the selected transmission path.

In another embodiment, the first signal selector 310 analyzes the composite aperture information provided from the control panel 130 to determine whether composite aperture information is input information for selecting the third ultrasound image. When it is determined that the composite aperture information is the input information for selecting the third ultrasound image, the first signal selector 310 selects the reception focusing signal (the first reception focusing signal or the second reception focusing signal) provided from the reception focusing unit 240, Signal to the composite aperture processing unit 320 and transmits the reception focusing signal to the composite aperture processing unit 320 through the selected transmission path.

The pulse compression unit 250 includes a synthesis aperture processing unit 320. The composite aperture processing unit 320 performs a composite aperture process on the receive focusing signals (any one of the first to fourth receive focusing signals) received from the first signal selector 310. 3, the composite aperture processing unit 320 includes a signal storage unit 312 for temporarily storing a reception focus signal provided from the first signal selection unit 310, An adder 314 which is operable to add the focus signal and the receive focus signal provided from the first signal selector 310 and the adder 314 which adds the receive focus signal stored in the signal storage 312 and the receive signal to the first signal selector 310, And a subtractor 316 which is operative to subtract the receive focus signal provided from the adder 316. [

In one embodiment, the composite aperture processor 320 performs composite aperture processing on the received focus signal provided from the first signal selector 310 to generate a signal corresponding to a second ultrasound image (i.e., a harmonic image) Hereinafter, referred to as a harmonic image signal).

In another embodiment, the composite aperture processor 320 performs composite aperture processing on the receive focusing signal provided from the first signal selector 310 to generate a signal corresponding to the third ultrasound image (hereinafter, Quot;).

The pulse compression unit 250 further includes a second signal selection unit 330. The second signal selection unit 330 analyzes the input information provided from the control panel 130 and transmits the reception focusing signal provided from the composite aperture processing unit 320 or the first signal selection unit 310 based on the analysis result (Not shown), and transmits a receive focusing signal through the selected transmission path.

In one embodiment, the second signal selector 330 analyzes pulse length information and composite aperture information provided from the control panel 130, and the pulse length information is input information for selecting the first pulse signal, And determines whether the information is input information for selecting the second ultrasound image. If it is determined that the pulse length information is the input information for selecting the first pulse signal and the composite aperture information is the input information for selecting the second ultrasound image, the second signal selector 330 may be provided from the composite aperture processor 320 The signal processing unit 260 selects a transmission path for transmitting the reception focusing signal to the signal processing unit 260 and outputs the reception focusing signal to the signal processing unit 260 through the selected transmission path, Lt; / RTI >

In another embodiment, the second signal selector 330 analyzes pulse length information and composite aperture information provided from the control panel 130, and the pulse length information is input information for selecting the first pulse signal, And determines whether the information is input information for selecting the third ultrasound image. If it is determined that the pulse length information is the input information for selecting the first pulse signal and the composite aperture information is the input information for selecting the third ultrasound image, the second signal selector 330 may be provided from the composite aperture processor 320 (Composite aperture image signal)) to the signal processing unit 260, and outputs a reception focusing signal to the signal processing unit 260 ).

In another embodiment, the second signal selector 330 analyzes the pulse length information provided from the control panel 130 to determine whether the pulse length information is input information for selecting the first pulse signal. If it is determined that the pulse length information is the input information for selecting the first pulse signal, the second signal selector 330 outputs the received focus signal (that is, the synthesized aperture signal received from the composite aperture processor 320) A harmonic image signal or a composite aperture image signal) to the signal processing unit 260, and transmits the reception focusing signal to the signal processing unit 260 through the selected transmission path.

In another embodiment, the second signal selector 330 analyzes the pulse length information and composite aperture information provided from the control panel 130, and the pulse length information is input information for selecting the second pulse signal, It is determined whether or not the aperture information is input information for selecting the first ultrasound image. If the pulse length information is input information for selecting the second pulse signal and the composite aperture information is input information for selecting the first ultrasound image, the second signal selector 330 selects the first pulse signal, To the correlation processing unit 350 to be described later, and transmits the reception focusing signal to the correlation processing unit 350 through the selected transmission path.

In another embodiment, the second signal selector 330 analyzes the pulse length information and composite aperture information provided from the control panel 130, and the pulse length information is input information for selecting the second pulse signal, It is determined whether or not the aperture information is input information for selecting the second ultrasound image. If it is determined that the pulse length information is the input information for selecting the second pulse signal and the composite aperture information is the input information for selecting the second ultrasound image, the second signal selector 330 may be provided from the composite aperture processor 320 (The harmonic image signal) to the correlation processing unit 350, and outputs the reception focusing signal to the correlation processing unit 350 through the selected transmission path, Lt; / RTI >

In another embodiment, the second signal selector 330 analyzes the pulse length information provided from the control panel 130 to determine whether the pulse length information is input information for selecting the second pulse signal. The second signal selector 330 selects the second pulse signal from the first signal selector 310 or the combining aperture processor 320 from the first signal selector 310 or the combining aperture processor 320, (Harmonic image signal)) to the correlation processing unit 350, selects a transmission path for transmitting the reception focusing signal through the selected transmission path to the correlation processing unit 350, To the processing unit (350).

The pulse compression unit 250 further includes a correlation coefficient table 340. [ The correlation coefficient table 340 is subjected to pulse compression processing (that is, correlation processing) on the reception-focused signal provided from the second signal selection unit 330 (that is, the reception- Processing). That is, the correlation coefficient table 340 stores a plurality of correlation coefficients corresponding to a plurality of pulse signals (pulse codes) for separating the pulse signals and pulse-compressing the separated pulse signals.

The pulse compression unit 250 further includes a correlation processing unit 350. The correlation processing unit 350 extracts a correlation coefficient corresponding to the input information (i.e., pulse length information) from the correlation coefficient table 340 and outputs the correlation coefficient corresponding to the reception And performs pulse compression processing (i.e., correlation processing) on the focusing signal.

4 is a flowchart illustrating a procedure for forming an ultrasound image according to an embodiment of the present invention. 4, the processor 120 forms a transmission signal (a first transmission signal or a second transmission signal) based on input information provided from the control panel 130 (S402), and transmits the formed transmission signal to a transmission / 220 to the ultrasonic transducer 112 (S404).

The processor 120 converts the received signal (the first received signal or the second received signal) provided from the ultrasonic transducer 112 through the transmit / receive switch 220 into a digital signal (a first digital signal or a second digital signal) (S406), and performs reception focusing on the converted digital signal to form a reception focusing signal (any one reception focusing signal among the first reception focusing signal to the fourth reception focusing signal) (S408).

The processor 120 analyzes input information (i.e., pulse length information and composite aperture information) provided from the control panel 130 (S410), and the pulse length information is input information for selecting the second pulse signal, It is determined whether the input information is the input information for selecting the second ultrasound image (S412).

If it is determined in step S412 that the pulse length information is the input information for selecting the second pulse signal and that the composite aperture information is the input information for selecting the second ultrasonic image, the processor 120 sets the reception focusing signal (I.e., the fourth receive focusing signal) (S414), and outputs the resultant receive focusing signal (i.e., the harmonic image signal) based on the correlation coefficient corresponding to the input information (I.e., correlation processing) is performed (S416). The processor 120 performs signal processing on the receive-focusing signal subjected to the pulse compression processing (S418), and forms a second ultrasound image based on the signal-processed receive focusing signal (S420).

If it is determined in step S412 that the pulse length information is the input information for selecting the second pulse signal and the composite aperture information is not the input information for selecting the second ultrasound image, It is determined whether the composite aperture information is input information for selecting the first ultrasound image (S422).

If it is determined in step S422 that the pulse length information is the input information for selecting the second pulse signal and the composite aperture information is the input information for selecting the first ultrasound image, the processor 120 determines the input information (i.e., pulse length information) (I.e., correlation processing) on the reception focusing signal (the third reception focusing signal or the fourth reception focusing signal) (S426) based on the correlation coefficient corresponding to the received reception signal, To form a first ultrasound image (S428).

If it is determined in step S422 that the pulse length information is the input information for selecting the second pulse signal and that the composite aperture information is not the input information for selecting the first ultrasound image, And determines whether the composite aperture information is input information for selecting the second ultrasound image or the third ultrasound image (S430).

If it is determined in step S430 that the pulse length information is input information for selecting the first pulse signal and the composite aperture information is input information for selecting the second ultrasound image or the third ultrasound image, The first receive focusing signal or the second receive focusing signal) (S432). The processor 120 performs signal processing on the synthesized calibrated received focus signal (i.e., the harmonic image signal or the synthesized caliber image signal) (S434), and generates a second ultrasound image or a second ultrasound image based on the signal- 3 ultrasonic image is formed (S436).

On the other hand, if it is determined in step S430 that the pulse length information is input information for selecting the first pulse signal, and that the synthesized aperture information is not the input information for selecting the second ultrasound image or the third ultrasound image, The signal processing is performed on the focusing signal (the first receiving focusing signal or the second receiving focusing signal) (S438), and the first ultrasonic image is formed based on the signal receiving receiving focusing signal (S440).

In the above-described embodiment, it is determined that the pulse length information is input information for selecting the second pulse signal, and the composite aperture information is input information for selecting the second ultrasonic image. Then, the pulse length information is input And the synthesized aperture information is input information for selecting the first ultrasound image. However, the present invention is not limited to this, and it is also possible to determine the pulse length information and synthesize aperture information in steps S412, S422, and S430 May be changed as needed.

5 is a flowchart illustrating a procedure of forming an ultrasound image according to another embodiment of the present invention. 5, the processor 120 forms a transmission signal (a first transmission signal or a second transmission signal) based on input information provided from the control panel 130 (S502), and transmits the formed transmission signal to a transmission / 220 to the ultrasonic transducer 112 (S504).

The processor 120 converts the received signal (the first received signal or the second received signal) provided from the ultrasonic transducer 112 through the transmit / receive switch 220 into a digital signal (a first digital signal or a second digital signal) (S506), and performs receive-focusing on the converted digital signal to form a receive-focusing signal (any one of the first to fourth receive-focusing signals) (S508).

The processor 120 analyzes synthesized aperture information provided from the control panel 130 (S510), and determines whether the composite aperture information is input information for selecting the second ultrasound image or the third ultrasound image (S512).

If it is determined in step S512 that the composite aperture information is the input information for selecting the second ultrasound image or the third ultrasound image, the processor 120 sets the receive focus signal (any one of the first receive focus signal to the fourth receive focus signal And a synthesizing aperture process is performed on the reception focusing signal (S514).

The processor 120 analyzes pulse length information provided from the control panel 130 (S516), and determines whether the pulse length information is input information for selecting the second pulse signal (S518).

If it is determined in step S518 that the pulse length information is the input information for selecting the second pulse signal, the processor 120 determines whether or not the received signal is a synthesized calibrated received signal based on the correlation coefficient corresponding to the input information (i.e., pulse length information) (I.e., correlation processing) on the harmonic image signal (i.e., the harmonic image signal) (S520). The processor 120 performs signal processing on the receive-focusing signal subjected to pulse compression processing (S522), and forms a second ultrasound image based on the signal-processed receive focusing signal (S524).

On the other hand, if it is determined in step S518 that the pulse length information is not the input information for selecting the second pulse signal (i.e., the pulse length information is the input information for selecting the first pulse signal) (S526), and forms a second ultrasound image or a third ultrasound image based on the signal-processed receive focusing signal (step S526) (S528).

On the other hand, if it is determined in step S512 that the composite aperture information is not the input information for selecting the second ultrasound image or the third ultrasound image (i.e., it is determined that the composite aperture information is the input information for selecting the first ultrasound image) The controller 120 analyzes pulse length information provided from the control panel 130 in step S530 and determines whether the pulse length information is input information for selecting the second pulse signal in step S532.

If it is determined in step S532 that the pulse length information is the input information for selecting the second pulse signal, the processor 120 generates a receive focusing signal (the third received signal) based on the correlation coefficient corresponding to the input information (I.e., a focus signal or a fourth receive focusing signal) (S534). The processor 120 performs signal processing on the receive-focusing signal subjected to pulse compression processing (S536), and forms a first ultrasound image based on the signal-processed receive focusing signal (S538).

On the other hand, if it is determined in step S532 that the pulse length information is not the input information for selecting the second pulse signal (i.e., the pulse length information is determined to select the first pulse signal) (S540), and forms a first ultrasound image based on the signal-processed receive focusing signal (S542).

In the above-described embodiments, the pulse length information is analyzed after analyzing the synthesized aperture information. However, the present invention is not limited to this, and the order of analyzing the pulse length information and the synthesized aperture information may be appropriately changed as needed.

While the present invention has been illustrated and described with respect to preferred embodiments thereof, it will be apparent to those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the appended claims.

100: Ultrasonic system 110: Ultrasonic probe
112: ultrasonic transducer 120: processor
130: Control panel 140: Output section
210: transmitting unit 220: transmitting / receiving switch
230: Receiving unit 240: Receiving focusing unit
250: pulse compression unit 260: signal processing unit
310: first signal selector 320: composite aperture processor
322: Signal storage unit 324:
326: subtractor 330: second signal selector
340: Correlation coefficient table 350: Correlation processor

Claims (19)

As an ultrasound system,
An ultrasonic probe operable to transmit an ultrasonic signal to a target object and to receive an ultrasonic echo signal reflected from the target object;
A receive focusing unit operable to form a receive focus signal based on the ultrasound echo signal;
At least one of a first signal processing for forming a harmonic image signal of a harmonic image or a composite image signal of a synthesized aperture image and a second signal processing for forming a pulse compressed signal based on pulse length information and composite aperture information A pulse compression unit operable to form an ultrasound image signal on the receive focusing signal; And
An ultrasound image forming unit for forming an ultrasound image based on the ultrasound image signal,
. The method according to claim 1,
Wherein the pulse length information includes information for selecting one of a first pulse signal having a first length as the ultrasonic signal and a second pulse signal having a second length longer than the first length,
Wherein the composite aperture information includes information for selecting either the fundamental ultrasound image of the fundamental frequency as the ultrasound image, the harmonic image having a frequency that is an integral multiple of the fundamental frequency, and the composite aperture image obtained by synthesizing a plurality of aperture images Ultrasound system. The pulse compressor according to claim 2,
A first signal selector operable to select one of transmission paths for transmitting the reception focusing signal based on the pulse length information and the composite aperture information;
A first signal processing unit operable to perform the first signal processing on the receive focusing signal provided from the first signal selecting unit;
And selecting one of transmission paths for transmitting the reception focusing signal provided from the first signal selection unit or the first signal processing unit according to the pulse length information and the composite aperture information, 2 signal selector; And
A second signal processing unit operable to perform the second signal processing on the receive focusing signal provided from the second signal selecting unit,
. The apparatus of claim 3, wherein the first signal selector comprises:
Determining whether the pulse length information is information for selecting the first pulse signal and whether the composite aperture information is information for selecting the harmonic image or the composite aperture image,
When the pulse length information is information for selecting the first pulse signal and it is determined that the composite aperture information is information for selecting the harmonic image or the composite aperture image, Selects a first transmission path for transmission to the first signal processing unit,
And to transmit the reception focusing signal provided from the reception focusing unit to the first signal processing unit through the first transmission path. The apparatus of claim 3, wherein the first signal selector comprises:
Determining whether the pulse length information is information for selecting the second pulse signal, whether the composite aperture information is information for selecting the basic ultrasound image,
When the pulse-length information is information for selecting the second pulse signal, and when it is determined that the composite aperture information is information for selecting the fundamental ultrasound image, the receive focusing signal provided from the receive- Selects a second transmission path for transmission to the selection unit,
And to transmit the receive focusing signal provided from the receive focusing unit to the second signal selector through the second transmission path. The apparatus of claim 3, wherein the first signal selector comprises:
Determining whether the pulse length information is information for selecting the second pulse signal, whether the composite aperture information is information for selecting the harmonic image,
Wherein the pulse-length information is information for selecting the second pulse signal, and when it is determined that the composite aperture information is information for selecting the harmonic image, the receive- Selects a third transmission path for transmission to the base station,
And to transmit the reception focusing signal provided from the reception focusing unit to the first signal processing unit through the third transmission path. The apparatus of claim 3, wherein the first signal selector comprises:
Determining whether the composite aperture information is information for selecting the harmonic image or the composite aperture image,
A fourth transmission path for transmitting the reception focusing signal provided from the reception focusing unit to the first signal processing unit is selected when it is determined that the composite aperture information is information for selecting the harmonic image or the composite aperture image ,
And to transmit the reception focusing signal provided from the reception focusing unit to the first signal processing unit through the fourth transmission path. The apparatus of claim 3, wherein the first signal selector comprises:
Determining whether the pulse length information is information for selecting the first pulse signal, whether the composite aperture information is information for selecting the basic ultrasound image,
When the pulse length information is information for selecting the first pulse signal and it is determined that the composite aperture information is information for selecting the basic ultrasound image, the receive focusing signal provided from the receive- Selects a fifth transmission path for transmission,
And to transmit the reception focusing signal provided from the reception focusing unit to the image forming unit through the fifth transmission path. The apparatus of claim 3, wherein the second signal selector comprises:
Determining whether the pulse length information is information for selecting the second pulse signal, whether the composite aperture information is information for selecting the basic ultrasound image,
When the pulse length information is information for selecting the second pulse signal and the composite aperture information is information for selecting the basic ultrasound image, the receive focusing signal provided from the first signal selector 2 signal processing unit, selects a sixth transmission path for transmission to the second signal processing unit,
And to transmit the receive focusing signal provided from the first signal selector to the second signal processor through the sixth transmission path. The apparatus of claim 3, wherein the second signal selector comprises:
Determining whether the pulse length information is information for selecting the second pulse signal, whether the composite aperture information is information for selecting the harmonic image,
When the pulse length information is information for selecting the second pulse signal, and when it is determined that the composite aperture information is information for selecting the harmonic image, the harmonic image signal provided from the first signal processing unit is referred to as the second signal Selects a seventh transmission path for transmission to the processing unit,
And to transmit the harmonic image signal provided from the first signal processing unit to the second signal processing unit through the seventh transmission path. The apparatus of claim 3, wherein the second signal selector comprises:
Determining whether the pulse length information is information for selecting the second pulse signal,
When the pulse length information is determined to be information for selecting the second pulse signal, the receiving focusing signal provided from the first signal selecting unit or the harmonic image signal provided from the first signal processing unit is converted into the second signal Selects an eighth transmission path for transmission to the processing section,
And to transmit the receive focusing signal provided from the first signal selection unit or the harmonic image signal provided from the first signal processing unit to the second signal processing unit through the eighth transmission path. The apparatus of claim 3, wherein the second signal selector comprises:
Determining whether the pulse length information is information for selecting the first pulse signal and whether the composite aperture information is information for selecting the harmonic image or the composite aperture image,
When the pulse length information is information for selecting the first pulse signal and it is determined that the composite aperture information is information for selecting the harmonic image or the composite aperture image, Or a ninth transmission path for transmitting the composite aperture image signal to the image forming unit,
And transmits the harmonic image signal or the composite aperture image signal provided from the first signal processing unit to the image forming unit through the ninth transmission path. A method of performing signal processing on a receive focus signal,
Transmitting an ultrasound signal to a target object and receiving an ultrasound echo signal reflected from the target object;
Forming a receive focusing signal based on the ultrasonic echo signal;
At least one of a first signal processing for forming a harmonic image signal of a harmonic image or a composite image signal of a synthesized aperture image and a second signal processing for forming a pulse compressed signal in accordance with pulse length information and composite aperture information, Forming ultrasound image signals on the receive focusing signals; And
Forming an ultrasound image based on the ultrasound image signal
≪ / RTI > 14. The apparatus of claim 13, wherein the pulse length information comprises information for selecting one of a first pulse signal having a first length as the ultrasound signal and a second pulse signal having a second length longer than the first length, Lt; / RTI >
Wherein the composite aperture information includes information for selecting either the fundamental ultrasound image of the fundamental frequency as the ultrasound image, the harmonic image having a frequency that is an integral multiple of the fundamental frequency, and the composite aperture image obtained by synthesizing a plurality of aperture images How to. 15. The method of claim 14, wherein performing at least one of the first signal processing and the second signal processing comprises:
Determines whether the pulse length information is information for selecting the first pulse signal, and whether the composite aperture information is information for selecting the harmonic image or the composite aperture image, by analyzing the pulse length information and the composite aperture information step; And
When the pulse length information is information for selecting the first pulse signal and it is determined that the composite aperture information is information for selecting the harmonic image or the composite aperture image, To form the harmonic image signal or the composite aperture image signal
≪ / RTI > 15. The method of claim 14, wherein performing at least one of the first signal processing and the second signal processing comprises:
Analyzing the pulse length information and the synthesized aperture information to determine whether the pulse length information is information for selecting the second pulse signal and whether the synthesized aperture information is information for selecting the fundamental ultrasound image; And
Wherein when the pulse length information is information for selecting the second pulse signal and the composite aperture information is information for selecting the primary ultrasound image, the second signal processing is performed on the receive focusing signal, The step of forming a compressed signal
≪ / RTI > 15. The method of claim 14, wherein performing at least one of the first signal processing and the second signal processing comprises:
Analyzing the pulse length information and the synthesized aperture information to determine whether the pulse length information is information for selecting the second pulse signal and whether the synthesized aperture information is information for selecting the harmonic image;
Wherein when the pulse length information is information for selecting the second pulse signal and the composite aperture information is information for selecting the harmonic image, the first signal processing is performed on the reception focusing signal, Forming a signal; And
Performing the second signal processing on the harmonic image signal to form the pulse-compressed signal
≪ / RTI > 15. The method of claim 14, wherein performing at least one of the first signal processing and the second signal processing comprises:
Analyzing the composite aperture information to determine whether the composite aperture information is information for selecting the harmonic image or the composite aperture image; And
Forming the harmonic image signal or the composite aperture image signal by performing the first signal processing on the receive focusing signal if it is determined that the composite aperture information is information for selecting the harmonic image or the composite aperture image,
≪ / RTI > A computer program stored on a medium for causing a computer to perform a method of performing signal processing on a receive focus signal,
Forming a receive focusing signal based on an ultrasonic echo signal reflected from the object;
At least one of a first signal processing for forming a synthesized aperture image signal of the harmonic image signal of the harmonic image or a synthesized aperture image and a second signal processing for forming the pulse compressed signal in accordance with the pulse length information and the synthesize aperture information Forming an ultrasound image signal on the receive focusing signal; And
Forming an ultrasound image based on the ultrasound image signal
And a computer program stored in the medium.

Images