CN100450443C - Receiving method and its device based on double beam and synthetic aperture - Google Patents
Receiving method and its device based on double beam and synthetic aperture Download PDFInfo
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Abstract
The present invention relates to a receiving method based on double wave beams and synthetic apertures, which is used for the wave beam synthesis of an ultrasonic imaging system with double wave beams. The receiving method based on double wave beams and synthetic apertures has the principle that an emitter emits wave beams twice in the same physical position, echo wave signals of each receiving array element corresponding to the same side of an emission center are selected by the system through a selecting device each time, and the data of two half wave beams are generated through a wave beam synthesizer. The data of the two-time half wave beams are added so as to obtain two wave beam signals scanned in the position. Thus, the number of receiving processing channels of the ultrasonic imaging system is reduced by half. The cost of a receiving circuit of the system is reduced under the condition of no loss of a scanning frame rate. The wave beam synthesis is controlled through a dynamic time-delay focusing parameter by the wave beam synthesizer which adopts the method. Distortion can be corrected by changing the dynamic time-delay focusing parameter by adopting a circular-arc correction method. Thus, the image quality of the ultrasonic imaging system is guaranteed simultaneously, and a proposal can be realized simply.
Description
Technical field
The present invention relates to ultrasonic technique, relate in particular to the signal processing in the medical ultrasound imaging system, particularly relate to the reception synthetic method of ultrasonic signal.
Background technology
Ultrasound imaging techniques is used widely in the modern medicine clinical diagnosis, and reducing cost and improving frame per second is the important goal that the ultrasonic image-forming system design is pursued: low cost is the product competitiveness key factor; Frame per second is the valuable resource of ultrasonic image-forming system, and high frame per second is for image quality, and is very crucial in blood flow and doppler imaging especially.In addition, improve frame per second, can reduce speckle noise effectively in conjunction with technology such as complex imagings.
Multi-beam is one of effective ways that improve frame per second.Because frame per second and emitting times are inversely proportional to, the few more frame per second of emitting times is high more, and described multi-beam is by launching the wave beam of a broad, receives a plurality of echo wave beams at the emission near axis, improves frame per second thereby receive with primary emission, multi-beam.But multi-beam is also brought a shortcoming: transmit and receive not on same axis on the one hand, receive backward energy come from transmits and receives between the line more, rather than come from the reception line, digital scan conversion (D.S.C) is according to the regular echo that uniformly-spaced shows on the other hand, will cause the image fault of demonstration like this.Specifically be described below: in simple beam emitting-receiving system shown in Figure 1, after each array element emission, array element receives echo-signal, beam synthesizer is to array element echo-signal delayed addition, wave beam focused on and received on the line this moment, receive the line and the line of departure and coincide, beam signal can correctly be shown through image behind the digital scan conversion.But in dualbeam emitting-receiving system shown in Figure 2, after each array element emission once, array element receives echo-signal, and beam synthesizer is to array element echo-signal delayed addition; Different with above-mentioned simple beam is that it focuses on simultaneously and forms two wave beams, promptly has two and receives line; Ideal two reception lines will depart from the emission axis as shown in the figure, and the ultrasonic echo energy peak is not to receive on the line in ideal, but between emission axis and reception axis; But the actual reception axis will depart from the desirable axis that receives, near the deviation value maximum at emission focus place; Because digital scan conversion is pressed the desirable line that receives to the wave beam composite signal requirement of input and is arranged, so actual dualbeam reception line will bring the distortion on the pictorial display.
United States Patent (USP) 5,779,640 have proposed a kind of multi-beam distortion correction system and method, and it is primarily aimed at colour and doppler imaging, has designed an azimuth space smoothing wave filter.The desirable position X of axis that receives of its supposition actual reception axis runout then according to multi-thread real data, inserts out the data that receive line in ideal approx with spatial filter, is used as process object.Because the effect of smoothing filter has bigger infringement to spatial resolution, therefore the realization of this bearing calibration is a cost with loss picture quality.United States Patent (USP) 6,282,963 propose a kind of multi-beam method of bifocus emission, realize that primary emission produces two launching centres, dualbeam focuses on does not so just need data to correct on two launching centres, but its cost is the cost that has increased radiating circuit greatly.
Summary of the invention
The technical problem to be solved in the present invention provides a kind of wave beam method of reseptance, can reduce the cost of receiving circuit under the situation that does not reduce frame per second or picture quality.
For solving the problems of the technologies described above, of the present inventionly be contemplated that substantially: adopt dualbeam and synthetic aperture technique combination, guarantee frame per second and reduce cost.Just, each array element, makes the multiplexing same receive path of each array element echo multichannel gradation, thereby can reduce the number of receive path by several selections that receives selector in same position emission twice, and then reduces system's receiving circuit cost.Consider the employing dualbeam, receive the line distortion, then can when not increasing system's extra cost, further guarantee picture quality if in receiving dynamic delay focusing, correct.
As the technical scheme that realizes the present invention's design be, a kind of method of reseptance based on dualbeam and synthetic aperture is provided, the number of the reception treatment channel of described ultrasonic image-forming system comprises step than not adopting the system of synthetic aperture to reduce half,
A. after emitter is launched for the first time, system is by the echo-signal that respectively receive array element of selecting arrangement reception from a certain side of relative launching centre, be sent to beam synthesizer after amplification through receiving treatment channel separately, the analog digital conversion respectively, generate the data of two preceding half-wave bundles, should described data be sent to memorizer;
B. emitter is after same position is launched for the second time, system is by the echo-signal that respectively receive array element of described selecting arrangement reception from relative launching centre opposite side, be sent to beam synthesizer after amplification through receiving treatment channel separately, the analog digital conversion respectively, generate the data of two later half wave beams; From described memorizer, take out described two preceding half-wave beam datas,, obtain B itself and described two later half beam data additions
n, B
N+1Two all-wave beam datas; Wherein n is a natural number 1,2,3 ..., the total emitting times of expression emitter;
C. with B
nData are sent to detector and digital scan convertor is for further processing, B
N+1It is temporary that data are sent to memorizer;
D. if scanning finishes as yet, continue following steps after then changing the physical location of emitter emission, finish until the scanning receiving course;
E. emitter is after launch for the first time new position, system receives the echo-signal that respectively receives array element that is same as the described side of step a from relative launching centre by described selecting arrangement, be sent to beam synthesizer after amplification through receiving treatment channel separately, the analog digital conversion respectively, generate the data of two preceding half-wave bundles; Should described data be sent to memorizer, with B in the memorizer
N+1Data are sent to detector and digital scan convertor is further handled;
F. repeat above-mentioned steps b~d;
Especially, among described step a, b or the e, described beam synthesizer is handled digital received echo-signal from each passage by time-delay focus control mode, and comes correcting distortion by the method that changes the dynamic delay focusing parameter; The calculating of described dynamic delay focusing parameter, receiving orthotic line with two is basis; Described two reception orthotic line are by the circular arc corrective method, produce in the following manner: described reception orthotic line is departed from the desirable line that receives with the direction that departs from launching centre, it is in the bias maximum at emission focus place, if its value is Q, then along with receiving the focal position away from the emission focus, its deviation value diminishes gradually, if the rectification radius is R, coordinate x (i) receives the vertical dimension that focal length receives the array element center, y (i) is that this point arrives described launching centre distance on the reception orthotic line, P is for receiving array element distance, and F is the emission focal length, then
And when y (i)<0.25P, make y (i)=0.25P
Compared with prior art, adopt technique scheme, can under the situation of not losing frame per second or picture quality, reduce the cost of ultrasonic image-forming system receiving circuit, and the circuit realization is simple, thereby makes product have more the market competitiveness.
Description of drawings
Fig. 1 is that the simple beam emission receives sketch map
Fig. 2 is that the dualbeam emission receives sketch map
Fig. 3 is that sketch map is corrected in the dualbeam dynamic focusing
Fig. 4 is based on the ultrasonic image-forming system block diagram of dualbeam and synthetic aperture
Fig. 5 is based on the beam synthesizer block diagram of dualbeam and synthetic aperture
Fig. 6 is based on the method for reseptance flow chart of dualbeam and synthetic aperture
The specific embodiment
Below, the most preferred embodiment shown in is set forth the present invention in conjunction with the accompanying drawings.
Easy for what narrate, suppose one 4 passage ultrasonic image-forming system (the real system port number is generally greater than 4), it also is 4 (the real system array number is generally more than or equal to port numbers) that system participates in emission reception array element, and it has the system structure based on dualbeam and synthetic aperture as shown in Figure 4.
Described ultrasonic image-forming system comprises: 4 probe array elements are used for to tested human body emission ultrasound wave and receiving target echo; 2 selectores, the reception of the array element that is used for respectively popping one's head in is selected, and its each input all connects a probe uniquely and receives array element, and each outfan all connects a channel amplifier uniquely; Described channel amplifier, be used to amplify selector output, from the reception echo-signal of probe array element, the signal after it amplifies is sent to the A/D changer and converts digital signal to; At least one beam synthesizer, be used for the digital signal of described each passage A/D changer output is focused on time-delay, weighting processing and summation, the output of described beam synthesizer send display to show by digital scan convertor (D.S.C) conversion after device detects after testing; Master controller is used for system control, comprises that generation is sent to the control signal of described beam synthesizer, detector, digital scan convertor respectively.
Wherein, for saving the number of receive path, system often adopts the selector of multiselect one.Among the present invention based on dualbeam, what employing was synthesized in the aperture is the alternative selector, the signal of two inputs that each outfan correspondence is respectively from symmetric two probe array elements on the position, thereby makes the number that receives treatment channel than not adopting the system of synthetic aperture to reduce half.As shown in the figure, receive from the echo of target each array element by probe, per two are connected to same selector with the symmetric probe array element of launching centre, i.e. array element 1,4 totally one selector, and array element 2,3 is totally one selector.Like this, when each array element when same position is launched twice based on dualbeam, two selectores are after emission for the first time, the reception echo of array element 1,2 that can select relative launching centre the same side respectively is as output, and after the emission for the second time, select the array element 3,4 of opposite side respectively, thereby help date processing.Certainly, a plurality of selectores in the above-mentioned example can replace with other forms of selecting arrangement, and the switch switching device shifter of the many outfans of for example many inputs is because of its effect is the same, all in protection scope of the present invention.
The present invention is based on the method for reseptance of dualbeam and synthetic aperture, the wave beam that is used for the dualbeam ultrasonic image-forming system is synthetic, the number of the reception treatment channel of described ultrasonic image-forming system is half of receiving transducer array element number, described method of reseptance principle is: after system transmitter is launched for the first time, the reception echo-signal of array element 1,2 respectively after two passages are handled, is formed the data of two preceding half-wave bundles as shown by beam synthesizer; After the emission, according to the reception echo-signal of array element 3,4, beam synthesizer forms the data of two later half wave beams for the second time.With the data addition of each two half-wave bundle of twice formation, promptly get the data of two all-wave bundles that array element 1,2,3,4 forms.Concrete method of reseptance is seen accompanying drawing 6, and step is specific as follows:
A. after emitter is launched for the first time, system chooses the echo-signal of array element 1,2 respectively by two selectores, be sent to beam synthesizer after amplification through receiving treatment channel separately, the analog digital conversion respectively, generate the data of two preceding half-wave bundles, described data are sent to memorizer;
B. emitter is after same position is launched for the second time, and system chooses the echo-signal of array element 3,4 respectively by two selectores, is sent to beam synthesizer after the amplification through receiving treatment channel separately, the analog digital conversion respectively, generates the data of two later half wave beams; From described memorizer, take out two preceding half-wave beam datas,, obtain B itself and described two later half beam data additions
n, B
N+1Two all-wave beam datas; (wherein n is a natural number 1,2,3 ..., the total emitting times of expression emitter);
C. with B
nData are sent to detector and digital scan convertor is further handled, B
N+1It is temporary that data are sent to memorizer;
D. if scanning finishes as yet, continue following steps after then changing the physical location of emitter emission, finish until the scanning receiving course;
E. emitter is after launch for the first time new position, and system chooses array element 1,2 echo-signals respectively by two selectores, is sent to beam synthesizer after the amplification through receiving treatment channel separately, the analog digital conversion respectively, generates the data of two preceding half-wave bundles; Described data are sent to memorizer, with B in the memorizer
N+1Data are sent to detector and digital scan convertor is further handled;
F. from above-mentioned steps b lifting multiple correlation operating procedure.
Each signal in above-mentioned steps receives in treatment channel, after being exaggerated from the signal of probe array element, is to be digitized with unified speed.
In multiple-beam system, can adopt similar bore diameter synthesizing technology, adopt multiselect one selector, make a plurality of probes receive array element by the multiplexing same reception treatment channel of selector.The present invention no longer describes it in detail.
In most preferred embodiment of the present invention, described beam synthesizer is handled digital received echo-signal from each passage by time-delay focus control mode.In order to proofread and correct the image fault that dualbeam brings, must make dualbeam receive line and the coincidence of desirable reception line, or overlap as far as possible.The present invention has adopted a kind of method by change dynamic delay focusing parameter to come correcting distortion.In correction system not, calculate the dynamic focusing delay parameter and receive line according to ideal and calculate, because the actual reception line can be drawn close to the line of departure, cause distortion thus.Based on this thought, present embodiment has adopted the circular arc corrective method, sees accompanying drawing 3 (sketch map is corrected in the dualbeam dynamic focusing).In this antidote, when calculating the dynamic delay focusing parameter, correct shown in the dynamic focusing line for as shown two, depart from the desirable line that receives with receiving line with the direction that departs from launching centre; It is established its value and is Q in the bias maximum at emission focus place, and then along with receiving the focal position away from the emission focus, its deviation value diminishes gradually.If the rectification radius is R, then two orthotic line respectively receive focus and to the launching centre range formula are:
When y (i)<0.25P, make y (i)=0.25P
Wherein, coordinate x (i) is the vertical dimension that receives focal length array element center, y (i) be this point from described orthotic line to array element launching centre distance.P is an array element distance, and F is the emission focal length.
Beam synthesizer based on above-mentioned dualbeam and synthetic aperture method of reseptance, comprise two wave beam synthesis modules and wave beam thereof time-delay control module, each wave beam synthesis module all receives the digital beam signal that each receive path A/D changer is sent here, described wave beam time-delay control module is controlled its corresponding wave beam synthesis module by the dynamic delay focusing parameter, finishes half-wave Shu Hecheng;
Become the mark control module, control described several wave beam synthesis modules, finish channel weighting;
Become the mark compensating module, export after synthetic beam data is become the mark compensation deals;
Memorizer and read-write control device thereof are used for storage or sense data, comprise the half-wave beam data of described wave beam synthesis module output, or the wave beam generated data; Also comprise
Several adders, the half-wave beam data that is used for described wave beam synthesis module is sent here, with the half-wave beam data addition that described memorizer is formerly stored, form complete wave beam generated data;
At least one controls tag unit, the control sign that provides odd-even alternation to change, system with decision-making: system is sent to the wave beam generated data that becomes the mark compensating module, is from described adder or described memorizer; Or the data of described memory stores are from described adder or described two wave beam synthesis modules.
This most preferred embodiment provide described beam synthesizer can be further with reference to as Fig. 5, with 4 passage ultrasonic image-forming systems is example, and the annexation that comprise two A/D changers, two wave beam synthesis modules and wave beam time-delay control module thereof, become the mark control module, becomes mark compensating module, memorizer and read-write control device thereof as mentioned above;
Two adders receive the half-wave beam data from wave beam 1 synthesis module and the output of wave beam 2 synthesis modules respectively, also receive the half-wave beam data from memorizer respectively;
Described beam synthesizer is also made the control sign with LN0, represent that with LN0=1 odd number time scanning receives (or emission, slightly following), LN0=0 represents that even number time scanning receives, divide two-way to be sent to two selectores respectively, wherein selector 1 is used for selecting a signal to be sent to change mark compensating module from the output of adder 1 or the output of memorizer, and the wave beam generated data after its compensation deals is as the output signal of system; Selector 2 is used for selecting a signal to be sent to memorizer from the output of the output of adder 1 or wave beam 2 synthesis modules.Like this, when odd number time scanning received, the preceding half-wave data storage of wave beam 1,2 was in memorizer, and second beam data of the different physical locations of preceding once (even number) scanning is read from memorizer, gives detector behind the aperture compensation; When even number time scanning receives, the preceding half-wave data of wave beam 1,2 from memorizer read and and later half wave beam addition form two all-wave bundle signals, first gives detector after becoming the mark compensation, second is returned and is stored in the memorizer.
Described two time-delay control modules will be according to the control of aforesaid circular arc corrective method realization to two wave beam synthesis modules.
Among above-mentioned all embodiment, memorizer preferably adopts dual port RAM, or other have the memorizer of first in first out mechanism, can be convenient to Design of System Software.Certainly, under the situation that read-write is allowed, almost can adopt any type of memory.
In the practical application, system participates in the array number of emission reception often greater than port number, adopts this moment some selecting arrangements to make the multiplexing same passage of a plurality of array elements usually, in this system, can use the inventive method equally, increase selecting arrangement of the present invention and make the system channel number reduce half.Use this system of the present invention also in the scope of protection of present invention.
On Project Realization, the circuit of above numerical portion or module can be partly or entirely by DSP (Digital SignalProcessing) technology, realize with high-speed real-time digital signal processing chip DSP (Digital Signal Processor), and use DSP on-chip memory or plug-in memorizer as required; Or, can use FPGA (Field Programmable Gate-Array field programmable gate array) programming to realize that embedded system only takies less system resource, all can reach the low cost of realizing.
Described method and apparatus is finished test on the hardware platform of the portable black-and-white B of our company, verify feasible.
Claims (4)
1. method of reseptance based on dualbeam and synthetic aperture, the wave beam that is used for the dualbeam ultrasonic image-forming system is synthetic, and the number of the reception treatment channel of described ultrasonic image-forming system comprises step than not adopting the system of synthetic aperture to reduce half
A. after emitter is launched for the first time, system is by the echo-signal that respectively receive array element of selecting arrangement reception from a certain side of relative launching centre, be sent to beam synthesizer after amplification through receiving treatment channel separately, the analog digital conversion respectively, generate the data of two preceding half-wave bundles, should described data be sent to memorizer;
B. emitter is after same position is launched for the second time, system is by the echo-signal that respectively receive array element of described selecting arrangement reception from relative launching centre opposite side, be sent to beam synthesizer after amplification through receiving treatment channel separately, the analog digital conversion respectively, generate the data of two later half wave beams; From described memorizer, take out described two preceding half-wave beam datas,, obtain B itself and described two later half beam data additions
n, B
N+1Two all-wave beam datas; Wherein n is a natural number 1,2,3 ..., the total emitting times of expression emitter;
C. with B
nData are sent to detector and digital scan convertor is for further processing, B
N+1It is temporary that data are sent to memorizer;
D. if scanning finishes as yet, continue following steps after then changing the physical location of emitter emission, finish until the scanning receiving course;
E. emitter is after launch for the first time new position, system receives the echo-signal that respectively receives array element that is same as the described side of step a from relative launching centre by described selecting arrangement, be sent to beam synthesizer after amplification through receiving treatment channel separately, the analog digital conversion respectively, generate the data of two preceding half-wave bundles; Should described data be sent to memorizer, with B in the memorizer
N+1Data are sent to detector and digital scan convertor is further handled;
F. repeat above-mentioned steps b~d;
It is characterized in that:
Among described step a, b or the e, described beam synthesizer is handled digital received echo-signal from each passage by time-delay focus control mode, and comes correcting distortion by the method that changes the dynamic delay focusing parameter;
The calculating of described dynamic delay focusing parameter, receiving orthotic line with two is basis; Described two reception orthotic line are by the circular arc corrective method, produce in the following manner: described reception orthotic line is departed from the desirable line that receives with the direction that departs from launching centre, it is in the bias maximum at emission focus place, if its value is Q, then along with receiving the focal position away from the emission focus, its deviation value diminishes gradually, if the rectification radius is R, coordinate x (i) receives the vertical dimension that focal length receives the array element center, y (i) is that this point arrives described launching centre distance on the reception orthotic line, P is for receiving array element distance, and F is the emission focal length
Then
And when y (i)<0.25P, make y (i)=0.25P.
2. the method for reseptance based on dualbeam and synthetic aperture according to claim 1 is characterized in that:
Among described step a, b or the e,, after being exaggerated from the signal of each described reception array element, be to be digitized with unified speed in each described reception treatment channel.
3. the method for reseptance based on dualbeam and synthetic aperture according to claim 1 is characterized in that:
Described selecting arrangement is a selector of using several alternatives consistent with receiving the treatment channel number, each this described selector receive respectively from symmetric two echo-signals that receive array elements of launching centre.
4. the method for reseptance based on dualbeam and synthetic aperture according to claim 1 is characterized in that:
Described memorizer adopts the memorizer with first in first out mechanism, comprises dual port RAM.
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CN109350115A (en) * | 2018-12-04 | 2019-02-19 | 珠海医凯电子科技有限公司 | Interlacing dualbeam method |
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