Patent Number: 
Section: claims

1. An ultrasonic front-end device for use in an ultrasonic system, compatible with P types of reception channels, where P is an integer larger than or equal to 1; the ultrasonic front-end device being connected between a probe and a detector of the ultrasonic system and controlled by a primary controller of the ultrasonic system; the probe having M array elements, where M is an integer larger than or equal to 1, the ultrasonic front-end device having an ultrasonic transmission part and an ultrasonic reception part, wherein the ultrasonic transmission part comprises a transmission beamformer and M transmission driving units, and has M transmission channels; the ultrasonic reception part comprises M high-voltage isolation circuits, RC amplifiers, RC analog-to-digital converters (ADCs) and a beamformer electrically connected in said order and has RC reception channels, where RC=[N,2N,3N . . . p*N], N being an integer larger than or equal to 1,being characterized in that,M low-voltage analog switches and a network of resistors are serially connected between the M high-voltage isolation circuits and the RC amplifiers, wherein M low-voltage analog switches are configured to electrically connect RC array elements of the M array elements in the probe and the RC respective reception channels in the ultrasonic reception part as the scan lines of the ultrasonic diagnostic system change, and the network of resistors configured to connect the RC reception channels connected by the M low-voltage analog switches with the RC amplifiers, the network of resistors comprising M inputs IN[1, 2, 3, . . . , M] connected to the outputs of the low-voltage analog switches and RC outputs OUT[1, 2, . . . , RC] connected to the inputs of the RC amplifiers; the structure of the network of resistors can be expressed by the following formula: OUT[jj]=IN[jj+kk*RC], indicating that the output OUT[jj] and the input IN[jj+kk*RC] of the network of resistors are connected through resistors, where 1<=jj<=RC, 0<=kk<=INT(M/RC), INT denotes taking the integer part, if jj+kk*RC>M, a corresponding input does not exist, and there is no resistor connecting the corresponding input and the output of the network of resistors; anda digital reordering unit included in the reception beamformer comprises a plurality of 2:1 multiplexers and a plurality of D-type flip-flops (DFFs) coupled thereto correspondingly. 2. The ultrasonic front-end device as set forth in claim 1, wherein the low-voltage switches are single-stage analog switches. 3. The ultrasonic front-end device as set forth in claim 1, wherein the connection between the network of resistors and the low-voltage analog switches and the amplifiers is implemented through resistors, wherein based on the number of RC, the corresponding resistors in the network of resistors are soldered with the low-voltage analog switches and the amplifiers. 4. The ultrasonic front-end device as set forth in claim 1, wherein the transmission beamformer comprises a transmission parameter storage unit and a transmission parameter reordering unit, wherein the outputs from the transmission parameter reordering unit being provided to the transmission driving units, and the transmission parameter reordering unit comprising a plurality of stages each having M 2:1 multiplexers followed with respective DFFs. 5. The ultrasonic front-end device as set forth in claim 4, wherein the transmission beamformer sets and stores a set of ordered transmission parameters corresponding to the transmission channels respectively, to provide a binary control parameter B[K, K−1,K−2, . . . , 0] which varies as the scan lines of the ultrasonic system change, the control parameter controls an array of 2:1 multiplexers to convert the ordered transmission parameters into parameters for the current transmission channels, the array of 2:1 multiplexers comprises multiple stages, each of which stage having M 2:1 multiplexers, each bit of the parameter B controls M 2:1 multiplexers at a corresponding stage, where 2K+1≧M K being an integer larger than or equal to 0,wherein the inputs at the 0th stage are the transmission parameters for the M transmission channels;each bit of the parameter B is used to control M 2:1 multiplexers at a stage: if the bit is 0, the data from the “0” inputs of the 2:1 multiplexers are output, otherwise, the data on the “1” inputs of the 2:1 multiplexers are output; the signals on the “1” inputs of the array of 2:1 multiplexers are shifted 2K units rightward, the shift complies with the binary coding format and the outputs from the 2:1 multiplexers at the last stage are M digitally reordered transmission parameters. 6. The ultrasonic front-end device as set forth in claim 1, wherein for the reception beamformer that performs digital reordering on the reception parameters, the digital reordering unit included in the reception beamformer comprises delay parameter digital reordering units and apodization parameter digital reordering units, the delay parameter digital reordering units and apodization parameter digital reordering units each comprising a plurality of stages each having P*N 2:1 multiplexers having a “0” input and a “1” input and DFFs coupled thereto correspondingly. 7. The ultrasonic front-end device as set forth in claim 6, wherein for the reception beamformer that performs digital reordering on the reception parameters, the digital reordering unit included in the reception beamformer comprises delay parameter digital reordering units and apodization parameter digital reordering units, the delay parameter digital reordering units and apodization parameter digital reordering units each comprising multiple stages of 2:1 multiplexers and DFFs connected thereafter, each stage having P*N 2:1 multiplexers having a “0” input and a “1” input and P*N DFFs coupled thereto correspondingly for the reception beamformer that performs digital reordering on the reception parameters, the reception beamformer sets and stores a set of ordered reception parameters corresponding to the reception channels respectively, to provide a binary control parameter C[K, K−1,K−2, . . . , 0] which varies as the scan lines of the ultrasonic system change, the control parameter controlling an array of 2:1 multiplexers to convert the ordered reception parameters into parameters for the current reception channels, the array of 2:1 multiplexers comprising K+1 stages, each stage having P*N 2:1 multiplexers, where 2K+1≧P*N K being an integer larger than or equal to 0,wherein the inputs of the P*N 2:1 multiplexers at the 0th stage are set to the ordered reception parameters for the corresponding reception channels, each bit of the parameter C is used to control 2:1 multiplexers at a corresponding stage: if the bit is 0, the data from the “0” inputs of the 2:1 multiplexers are output, otherwise, the data on the “1” inputs of the 2:1 multiplexers are output; the signals on the “1” inputs of the whole array of 2:1 multiplexers are shifted 2K units rightward, signals on the inputs of the multiplexers at the C[0] stage are shifted 1 unit rightward, signals on the inputs of the multiplexers at the C[1] stage are shifted 2 units rightward, signals on the inputs of the multiplexers at the C[2] stage are shifted 4 units rightward, . . . , and signals on the inputs of the multiplexers at the C[K] stage are shifted 2K units the shift complies with the binary coding format, and the outputs from the 2:1 multiplexers at the last stage are P*N digitally reordered reception parameters. 8. The ultrasonic front-end device as set forth in claim 1, wherein for the reception beamformer that performs digital reordering on the received signals, the digital reordering unit included in the reception beamformer comprises multiple stages of 2:1 multiplexers and DFFs connected thereafter, each stage comprising a plurality of stages each having P*N 2:1 multiplexers having a “0” input and a “1” input and P*N DFFs coupled thereto correspondingly;based on a binary control parameter C[K, K−1,K−2, . . . , 0] which varies as the scan lines of the ultrasonic system change, an array of 2:1 multiplexers are controlled to perform digital reordering on the received signals, the array of 2:1 multiplexers including k+1 stages, each stage having P*N 2:1 multiplexers, where 2K+1≧P*N K being an integer larger than or equal to 0,wherein signals from the ADCs are received at the inputs of the P*N 2:1 multiplexers at the 0th stage, each bit of the control parameter C is used to control M 2:1 multiplexers at a corresponding stage: if the bit is 0, the data from the “0” inputs of the 2:1 multiplexers are output, otherwise, the data from the “1” inputs of the 2:1 multiplexers are output; the signals on the “1” inputs of the array of 2:1 multiplexers are shifted 2K units rightward, the signals on the inputs of the multiplexers at the C[0] stage are shifted 1 unit rightward, the signals on the inputs of the multiplexers at the C[1] stage are shifted 2 units rightward, the signals on the inputs of the multiplexers at the C[2] stage are shifted 4 units rightward, the signals on the inputs of the multiplexers at the C[3] stage are shifted 8 units rightward, . . . , and the signals on the inputs of the multiplexers at the C[K] stage are shifted 2K units rightward, the shift complies with the binary coding format and the outputs from the 2:1 multiplexers at the last stage are P*N digitally reordered signals. 9. A operating method of an ultrasonic front-end device in an ultrasonic diagnostic system, wherein the ultrasonic front-end device is compatible with P types of reception channels, where P is an integer larger than or equal to 1; the ultrasonic front-end device is connected between a probe and a detector of the ultrasonic system and controlled by a primary controller of the ultrasonic system, the probe comprising M array elements, where M is an integer larger than or equal to 1, the ultrasonic front-end device comprising an ultrasonic transmission part and an ultrasonic reception part, wherein the ultrasonic transmission part comprises a transmission beamformer and M transmission driving units, and has M transmission channels, and the ultrasonic reception part has RC reception channels, where RC=[N,2N,3N . . . p*N], N being an integer larger than or equal to 1, and comprises M high-voltage isolation circuits, RC amplifiers, RC analog-to-digital converters (ADCs) and a beamformer electrically connected in said order, wherein, M low-voltage analog switches and a network of resistors are serially connected between the M high-voltage isolation circuits and the RC amplifiers, the M low-voltage analog switches are configured to electrically connect RC array elements of the M array elements in the probe and the RC corresponding reception channels in the ultrasonic reception part as the scan lines of the ultrasonic system change; the network of resistors is configured to connect the RC reception channels connected by the M low-voltage analog switches with the RC amplifiers, the network of resistors comprises M inputs IN[1, 2, 3, . . . , M] connected to the outputs of the low-voltage analog switches and RC outputs OUT[1, 2, . . . , RC] connected to the inputs of the amplifiers, the structure of the network of resistors is expressed by the following formula: OUT[jj]=IN[jj+kk*RC], indicating that the output OUT[jj] and the input IN[jj+kk*RC] of the network of resistors are connected through resistors, where IRC), INT denotes taking the integer part, if jj+kk*RC>M, since such a corresponding input does not exist, and there is no resistor connecting the corresponding input and the output of the network of resistors; and a digital reordering unit included in the reception beamformer comprises a plurality of 2:1 multiplexers and a plurality of D-type flip-flops (DFFs coupled thereto correspondingly, the method comprising the steps of:(1) emitting pulses by the ultrasonic transmission part with transmission parameters, to activate the currently selected transmission array elements in the probe of the ultrasonic system to transmit ultrasonic waves;(2) receiving echoes of the ultrasonic waves and converting them into electric signals by the currently selected reception array elements in the probe;(3) receiving the electric signals from the probe by the high-voltage isolation circuits in the ultrasonic reception part;(4) electrically connecting, by the M low-voltage analog switches in the ultrasonic reception part, RC array elements of the M array elements in the probe and RC corresponding reception channels in the ultrasonic reception part as the scan lines of the ultrasonic diagnostic system change;(5) connecting, by the network of resistors, the RC reception channels connected by the M low-voltage analog switches with the RC amplifiers;(6) amplifying and analog-to-digital (AD) converting the received electric signals by the amplifiers and the ADCs in the ultrasonic reception part; and(7) digital reordering the reception parameters or the received signals, and beam forming by the beamformer in the ultrasonic reception part. 10. The method as set forth in claim 9, wherein the step (1) further comprises the substeps of:(1a) setting and storing, by the transmission beamformer in the ultrasonic transmission part, a set of ordered transmission parameters corresponding to the transmission channels; and(1b) providing, by the transmission beamformer, a binary control parameter B[K, K−1,K−2, . . . , 0] which varies as the scan lines of the ultrasonic system change; the parameter controls an array of 2:1 multiplexers to convert the ordered transmission parameters into parameters for the current transmission channels; the array of 2:1 multiplexers comprises a plurality of stages each having M 2:1 multiplexers, each bit of the parameter controls M 2:1 multiplexers at a corresponding stage, where 2K+≧M K being an integer larger than or equal to 0; the inputs at the 0th stage are the ordered transmission parameters for the M transmission channels; each bit of the parameter B is used to control M 2:1 multiplexers at a corresponding stage: if the bit is 0, the data on from “0” inputs of the 2:1 multiplexers are output, otherwise, the data on the “1” inputs of the 2:1 multiplexers are output; the signals on the “1” inputs of the array of 2:1 multiplexers are shifted 2K units rightward, the signals on the inputs of the multiplexers at the B[0] stage are shifted 1 unit rightward, the signals on the inputs of the multiplexers at the B[1] stage are shifted 2 units rightward, the signals on the inputs of the multiplexers at the B[2] stage are shifted 4 units rightward, the signals on the inputs of the multiplexers at the B[3] stage are shifted 8 units rightward, and the signals on the inputs of the multiplexers at the B[K] stage are shifted 2K units rightward, the shift complies with the binary coding format, and the outputs from the 2:1 multiplexers at the last stage are M digitally reordered transmission parameters. 11. The method as set forth in claim 9, wherein for the reception parameters, the step (7) comprises the substeps of:(7a) setting and storing a set of ordered reception parameters corresponding to the reception channels, by the reception beamformer in the ultrasonic reception part; and(7b) providing, by the reception beamformer, a binary control parameter C[K, K−1,K−2, . . . , 0] which varies as the scan lines of the ultrasonic system change, the control parameter controlling an array of 2:1 multiplexers to convert the ordered reception parameters into parameters for the current reception channels; the array of 2:1 multiplexers comprises multiple stages each having P*N 2:1 multiplexers, each bit of the parameter controls P*N 2:1 multiplexers at a corresponding stage, where 2K+1≧P*N K being an integer larger than or equal to 0, wherein all the inputs of the P*N 2:1 multiplexers at the 0th stage are the reception parameters for the corresponding reception channels; each bit of the parameter C is used to control 2:1 multiplexers at a corresponding stage: if the bit is 0, the data from the “0” inputs of the 2:1 multiplexers are output, otherwise, the data from the “1” inputs of the 2:1 multiplexers are output; the signals on the “1” inputs of the whole array of 2:1 multiplexers are shifted 2K units rightward, the signals on the “1” inputs of the multiplexers at the C[0] stage are shifted 1 unit rightward, the signals on the “1” inputs of the multiplexers at the C[1]stage are shifted 2 units rightward, the signals on the “1” inputs of the multiplexers at the C[2] stage are shifted 4 units rightward, and the signals on the “1” inputs of the multiplexers at the C[K] stage are shifted 2K units rightward; the shift complies with the binary coding format, and the outputs from the 2:1 multiplexers at the last stage are P*N digitally reordered reception parameters. 12. The method as set forth in claim 9, wherein for the received signals, the digital reordering and beam forming at the step (7) comprises a substep of:providing, by the reception beamformer, a binary control parameter C[K, K−1,K−2, . . . 0] which varies as the scan lines of the ultrasonic system change, the control parameter controls an array of 2:1 multiplexers; the array of 2:1 multiplexers includes k+1 stages each having P*N 2:1 multiplexers, where 2K+1≧p*N K being an integer larger than or equal to 0, wherein signals from the ADCs are received by the inputs of the P*N 2:1 multiplexers at the 0th stage, each bit of the control parameter C is used to control P*N 2:1 multiplexers at a corresponding stage: if the bit is 0, the data from the “0” inputs of the 2:1 multiplexers are output, otherwise, the data from the “1” inputs of the 2:1 multiplexers are output; the signals on the “1” inputs of the array of 2:1 multiplexers are shifted 2K units rightward, the signals on the inputs of the multiplexers at the C[0] stage are shifted 1 unit rightward, the signals on the inputs of the multiplexers at the C[1] stage are shifted 2 units rightward, the signals on the inputs of the multiplexers at the C[2] stage are shifted 4 units rightward, the signals on the inputs of the multiplexers at the C[3] stage are shifted 8 units rightward, and the signals on the inputs of the multiplexers at the C[K] stage are shifted 2K units rightward, the shift complies with the binary coding format, and the outputs from the 2:1 multiplexers at the last stage are P*N digitally reordered signals.