公开(公告)号：US20140188419A1

公开(公告)日：2014-07-03

申请号：US14057544

申请日：2013-10-18

Applicant: University of Electronic Science and Technology of China

Inventor： Hao ZENG ,  Peng YE ,  Kuojun YANG ,  Guang YANG ,  Qinchuan ZHANG

IPC: G01R13/22 ,  G01R35/00

CPC classification number: G01R13/0272 ,  G01R13/0254

Abstract: The present invention provides a method for measuring the waveform capture rate of parallel digital storage oscilloscope. On the basis of double pulse measurement, and in consideration of the asymmetry of acquisition and the refreshing time of parallel DSO, the present invention provides a step amplitude-frequency combined pulse measurement to measure the time for waveform acquisition and mapping Tmap, the number of captured waveforms before LCD refreshing Wacq and the dead time caused by LCD refreshing TDDT, and then calculates the actual measured average WCR of parallel DSO, according to the measured data, so that the WCR of parallel can be measured.

Abstract translation: 本发明提供了一种用于测量并行数字存储示波器的波形捕获率的方法。 在双脉冲测量的基础上，考虑到并行DSO的采集不对称性和刷新时间，本发明提供了一种步进幅度 - 频率组合脉冲测量，以测量波形采集和映射时间Tmap，数量 在LCD刷新Wacq之前捕获的波形和由LCD刷新TDDT造成的死区时间，然后根据测量数据计算并行DSO的实际测量平均WCR，从而可以测量并行WCR。

公开(公告)号：US20180149676A1

公开(公告)日：2018-05-31

申请号：US15879146

申请日：2018-01-24

Applicant: UNIVERSITY OF ELECTRONIC SCIENCE AND TECHNOLOGY OF CHINA

Inventor： Kuojun YANG ,  Wuhuang HUANG ,  Peng YE ,  Qinchuan ZHANG ,  Hao ZENG ,  Duyu QIU ,  Jun JIANG ,  Huiqing PAN ,  Lianping GUO ,  Feng TAN

IPC: G01R13/02

Abstract: A method for oscilloscope 3D mapping in scan mode. The input signal is acquired using a real-time sampling rate which is Dr times higher, thus more sampling points, i.e. Dr acquired data can be obtained during the time interval between two consecutive horizontal pixels. The Dr acquired data are mapped into a same column of the screen to implement fluorescent waveform display. In addition, to realize the scanning display, a flag X is introduced into the three-dimensional database, when the screen refresh signal arrives, the first Ds acquired data are read out from the unread acquired data in FIFO memory. The three-dimensional database is updated from the flag X, which make the leftmost waveform always be the oldest waveform, the rightmost waveform always be the newest waveform. Thus the 3D mapping is realized in scan mode, letting the DSO have a fluorescent waveform display at slow time-base.

公开(公告)号：US20170373638A1

公开(公告)日：2017-12-28

申请号：US15696533

申请日：2017-09-06

Applicant: UNIVERSITY OF ELECTRONIC SCIENCE AND TECHNOLOGY OF CHINA

Inventor： Peng YE ,  Feng TAN ,  Xingqi LIU ,  Duyu QIU ,  Lianping GUO ,  Kuojun YANG ,  Qinchuan ZHANG ,  Huiqing PAN

IPC: H03B5/04 ,  H03B5/32

CPC classification number: H03B5/04 ,  H03B5/32 ,  H03L1/022 ,  H03L1/028

Abstract: The present invention provides a temperature-compensated crystal oscillator based on digital circuit, a closed-loop compensation architecture is employed to realize the high precision compensation of the crystal oscillator. The output frequency f(T) of the TCXO to be compensated is directly connected with the compensation voltage Vc(T) in real time, and the compensation voltage is fed back to the voltage control terminal of the VCXO to be compensated to compensate, so that the output frequency after compensation is equal to the target frequency signal, thus avoiding the frequency shift of output signal caused by temperature hysteresis, i.e. the discrepancy between the temperature acquired by a temperature senor and the real temperature of the resonant wafer in the prior art.

公开(公告)号：US20190392551A1

公开(公告)日：2019-12-26

申请号：US16435465

申请日：2019-06-08

Applicant: University of Electronic Science and Technology of China

Inventor： Wuhuang HUANG ,  Pan WANG ,  Jun JIANG ,  Peng YE ,  Kuojun YANG ,  Lianping GUO ,  Hao ZENG ,  Shuo WANG ,  Jian GAO

IPC: G06T1/60 ,  G06F16/22 ,  G06F3/06 ,  G06T11/20 ,  G01R13/02

Abstract: The present invention provides a method for 3D waveform mapping of full-parallel structure, first, a 3D waveform mapping database is created according to the size of a 3D waveform image, the number of bits of probability value and the ADC's resolution of data acquisition module, then the 3D waveform mapping database is divided into Mt×Ma independent mapping storage areas along the time axis and the amplitude axis, and each independent mapping storage area is assigned a RAM, then RAMs are selected and addresses are calculated based on the sampling values and the structure of created 3D waveform mapping database, finally, parallel mappings are performed simultaneously on the time axis and the amplitude axis according to the selected RAMs and calculated addresses. Thus, the mapping time are shorten, especially in vector mapping mode, several RAMs are used for mapping, so the WCR of DSO is improved.

公开(公告)号：US20180013384A1

公开(公告)日：2018-01-11

申请号：US15711430

申请日：2017-09-21

Applicant: UNIVERSITY OF ELECTRONIC SCIENCE AND TECHNOLOGY OF CHINA

Inventor： Feng TAN ,  Duyu QIU ,  Peng YE ,  Jiquan CHEN ,  Lianping GUO ,  Hao ZENG ,  Shuo ZHANG ,  Ke TANG

IPC: H03B5/04 ,  H03L1/02 ,  H03B5/36

CPC classification number: H03B5/04 ,  H03B5/366 ,  H03L1/02 ,  H03L1/023 ,  H03L1/028 ,  H03L7/00 ,  H03L7/06

Abstract: Disclosed is a temperature-compensated crystal oscillator based on analog circuit; a closed-loop compensation architecture determines the temperature compensation of a crystal oscillator. The power splitter divides the VCXO's current output signal with frequency f=f0+Δf into two signals, one signal to output of the TCXO and the other signal is sent to an analog frequency-voltage conversion circuit. According to the frequency of the VCXO's current output signal, the analog frequency-voltage conversion circuit produces a voltage signal V(T), which corresponds to current ambient temperature. The difference between V(T) and a reference voltage signal Vref is produced and amplified to obtain a compensation voltage signal ΔV through a voltage matching circuit. ΔV is smoothed by a filter, then sent to the voltage control terminal of the VCXO to make the VCXO generate a stable signal with desired frequency f0, to compensate the frequency of the VCXO's output signal when the ambient temperature is changed.

公开(公告)号：US20160097743A1

公开(公告)日：2016-04-07

申请号：US14933648

申请日：2015-11-05

Applicant: UNIVERSITY OF ELECTRONIC SCIENCE AND TECHNOLOGY OF CHINA

Inventor： Feng TAN ,  Duyu QIU ,  Peng YE ,  Hao ZENG ,  Yong ZHAO ,  Jun JIANG ,  Huiqing PAN ,  Lianping GUO ,  Shuhao WU

IPC: G01N29/02

CPC classification number: G01N29/022 ,  G01N29/036 ,  G01N29/4436 ,  G01N2291/014 ,  G01N2291/02818 ,  G01N2291/0426

Abstract: The present invention provides a method for a method for measuring the properties of liquid based on a quartz crystal microbalance sensor, which employs two measurements to obtain two frequency shifts of the QCM sensor induced by two different volume of the sample liquid. The present invention creatively established the relationship between the density and viscosity of sample liquid and the frequency shifts of QCM sensor. With present invention, the density and viscosity of sample liquid can be obtained through two frequency shifts. Comparing to the conventional liquid property measurement. The measuring procedure of present invention are more simple, and the measuring results are more accurate. Moreover, the present invention consumes less volume of sample liquid, and has the features such as online, real time and quantitative.

Abstract translation: 本发明提供了一种用于测量基于石英晶体微量天平传感器的液体性质的方法，该方法采用两次测量来获得由两个不同体积的样品液体引起的QCM传感器的两个频移。 本发明创造性地建立了样品液体的密度和粘度与QCM传感器的频移之间的关系。 通过本发明，可以通过两次频移获得样品液体的密度和粘度。 与传统的液体性能测量相比。 本发明的测量方法更简单，测量结果更准确。 此外，本发明消耗较少的样品液体量，具有在线，实时和定量等特征。

公开(公告)号：US20150188560A1

公开(公告)日：2015-07-02

申请号：US14584599

申请日：2014-12-29

Applicant: UNIVERSITY OF ELECTRONIC SCIENCE AND TECHNOLOGY OF CHINA

Inventor： Wuhuang HUANG ,  Kuojun YANG ,  Houjun WANG ,  Jun JIANG ,  Hao ZENG ,  Duyu QIU ,  Peng YE ,  Qinchuan ZHANG ,  Shulin TIAN

IPC: H03M1/12

CPC classification number: H03M1/128 ,  G06F3/038 ,  G06F3/044 ,  G06T17/20 ,  H03M1/00 ,  H03M1/12 ,  H03M1/1285

Abstract: For the signal under acquisition which varies monotonically before and after the trigger time, a method for full-digital random sampling employs first sampled data before the trigger time and first sampled data after the trigger time to fit a curve, and obtains an intersection point of triggering level and the fitted curve, then, calculates the time interval between sampled data after the trigger time and the intersection point in the end, reconstructs the original signal, i.e. the signal under acquisition by a time interval of each acquisition. Thus, an analog trigger circuit and a time measurement circuit of conventional random sampling system can be eliminated, that simplifies the circuit design of data acquisition system and decreases its hardware complexity. Moreover, the higher sampling rate for the signal under acquisition is attained, and more waveform details are obtained.

Abstract translation: 对于在触发时间之前和之后单调变化的信号，全数字随机采样的方法在触发时间之前采用第一采样数据，并在触发时间之后采用第一采样数据以拟合曲线，并获得 触发电平和拟合曲线，然后计算触发时间之后的采样数据与最终交点之间的时间间隔，重建原始信号，即每次采集时间间隔内的采集信号。 因此，可以消除常规随机采样系统的模拟触发电路和时间测量电路，简化了数据采集系统的电路设计，降低了硬件复杂度。 此外，获得获取信号的较高采样率，并获得更多的波形细节。