CN117743927B - Time sequence signal analysis method based on multi-mode sensing input library network - Google Patents
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Abstract
The invention discloses a time sequence signal analysis method based on a multi-mode sensing input library network, and belongs to the technical field of sensing and memory calculation integration and intelligent recognition. The method utilizes a multi-mode sensing input library network to correspond to nonlinear responses of a plurality of same-type multi-mode sensing fusion synaptic devices biased by different temperatures; the input time sequence signals are respectively applied to the multi-mode sensing fusion synaptic devices in the form of optical signals, photo-generated current response is generated along with the application of illumination, channel current values of the devices are used as library node states in a multi-mode sensing input library network, when illumination and temperature are changed simultaneously, channel current changes in real time along with the input of the two modes, the expression of fusion characteristics of the photo-thermal signals is generated, and the fitted time sequence signals are output through linear weight weighting. The invention successfully simulates the biological rhythm of the drosophila when the drosophila is in the coexistence of periodic illumination, periodic temperature and the periodic temperature, and is better than the fitting performance of the same-scale multi-layer perceptron and the recurrent neural network.
Description
Technical Field
The invention relates to a time sequence signal analysis (multimodal temporal SIGNAL ANALYSIS algorithm based on parallel multisensory reservoir computing) method based on a multi-mode sensing input library network, belonging to the technical field of sensing and memory calculation integration and intelligent identification.
Background
The multi-mode sensing technology realizes comprehensive sensing of complex environments by integrating information acquired by various sensors. And processing the multi-source time sequence data, and mining the internal association among the multi-mode data through joint analysis to acquire more comprehensive context description on environmental characteristics, so as to improve the understanding and decision-making force of the system on the event. The traditional time sequence signal analysis technology mainly focuses on single-mode time sequence data, adopts algorithms such as decision trees, support vector machines, random forests and the like to classify the data, or uses models such as linear regression, ARIMA models, long-short-term memory networks and the like to model and predict the data, is limited by data isomerism and redundancy when multi-mode input is processed, cannot fully extract nonlinear characteristics among cross-mode data and mine potential information among different-mode data, and greatly limits the calculation efficiency and processing performance of an information processing system on large-scale multi-mode data streams. In contrast, the multi-mode sensing synaptic device is used for collecting and fusion analysis of environmental data in real time, so that association mining and collaborative analysis between space-time concurrent data can be promoted, and a solid foundation is provided for subsequent feature extraction and pattern recognition. However, to accomplish analysis of the multi-modal fusion features of the fuzzy expression, the information processing algorithm is required to have feature analysis capabilities which are strongly related to hardware. The library network calculation realizes the function of extracting high-dimensional nonlinear characteristics from input through the nonlinear conversion capability in the development dynamics system, and has the surprise potential in the field of time sequence data processing, so that the novel hardware and architecture design based on the library network algorithm is urgently required to be explored to realize the efficient analysis of the multi-mode time sequence signals.
Disclosure of Invention
The invention provides a time sequence signal analysis method realized by utilizing a multi-mode fusion sensing synaptic device, which realizes high-efficiency integration and deep analysis of multi-mode time sequence data.
The technical scheme provided by the invention is as follows:
a time sequence signal analysis method based on a multi-mode sensing input library network comprises the following specific steps:
1) The multi-mode sensing input library network corresponds to nonlinear responses of a plurality of same-type multi-mode sensing fusion synaptic devices biased by different temperatures;
2) The input timing signals are respectively applied to the multi-mode sensing fusion synaptic device in the form of optical signals, the device generates a photoproduction current response along with the application of illumination, the channel current of the device is expressed as I (t) =I (t-1) ·αe -t/τ +f (u (t), I (t-1)), wherein u (t) represents the optical signal input at the current time t, I (t) represents the channel current of the device at the current time t under optical excitation, I (t-1) represents the channel current of the device at the time before optical excitation, αe -t/τ is a memory retention factor of e exponential decay, and f represents the nonlinear response current of the device to the current optical input based on the channel current state at the time t-1;
3) And taking the channel current value I (t) of the device as a library node state in the multi-mode sensing input library network, generating the expression of fusion characteristics of the photothermal signals by changing the channel current value in real time along with the input of two modes when illumination and temperature are changed simultaneously, and outputting a fitted time sequence signal through linear weight weighting.
Further, the multi-mode sensing fusion synaptic device comprises a back gate substrate with a dielectric layer covered on the surface and a nanosheet channel layer for sensing, an interface defect layer is arranged between the nanosheet channel layer and the dielectric layer, and source electrodes and drain electrodes are arranged on two sides of the nanosheet channel layer.
The nano-sheet channel layer is made of bismuth-oxygen selenium material, and the thickness is in the range of 5-20 nm. The substrate is a heavily doped silicon/hafnium oxide substrate wherein the hafnium oxide layer has a thickness in the range of 10-20 nm. The source electrode and the drain electrode are composed of Ti/Au metal lamination layers, the total thickness is not more than 100nm, and the interface defect layer is introduced by hydrofluoric acid wet etching.
The invention has the following advantages:
1) According to the invention, the multi-mode fusion sensing synaptic device is utilized, the characteristic analysis capability of the library network for calculating the strong correlation with hardware is exerted, the correlation mining is carried out on space-time concurrency data, the extracted fusion characteristic is expressed in a fuzzy manner, and the efficient integration and the deep analysis of the multi-mode time sequence data are realized.
2) The multi-modal fusion sensing synaptic device has multi-modal channel input capability, allows parallel input of multi-source information, fully allows potential nonlinear characteristics among space-time concurrent data to be subjected to joint analysis, greatly improves calculation parallelism, and has extremely high instantaneity by adopting a multi-library network parallel calculation mode in a library network calculation architecture.
3) The multi-mode fusion sensing synaptic device has wide response capability for multi-mode stimulation, so that the multi-mode fusion sensing synaptic device can dynamically and flexibly adapt to common input of different sub-modes or multiple modes, and the output captures the remarkable characteristics of each mode, so that the multi-mode fusion sensing synaptic device can easily cope with extreme cases such as mode deletion and the like.
Drawings
FIG. 1 is a schematic diagram of a multi-modal fusion sensing synaptic device for use with the present invention;
FIG. 2 is a schematic flow chart of the present invention, wherein P represents an input optical signal, M represents a time-sharing mask added to the input, T 1~TN represents different temperatures, and τ 1~τN represents relaxation times of the device to the optical input at the different temperatures;
FIG. 3 is a graph of current response of a multi-modal fusion sensing synaptic device for the same single light pulse at different temperatures, EPSC is an abbreviation for excitatory (excitatory postsynaptic current, EPSC) post-synaptic current, I ph represents photocurrent, graph (a) is the change over time of channel current of the multi-modal fusion sensing synaptic device at different temperatures for the same light pulse, and graph (b) is the values of current relaxation time and pulse first point photocurrent at different temperatures extracted from graph (a);
FIG. 4 is a graph of current response and photocurrent response of a multi-modal fusion sensing synaptic device at different temperatures and different light intensities, with (a) being the graph of current response at different temperatures and different light intensities and (b) being the photocurrent response at different temperatures and different light intensities;
FIG. 5 shows the input and output results of the present invention in a waveform classification task, and the response currents of the device to the optical input of the classification task at different temperatures, with FIG. (a) showing the response currents of the device to the optical input of the waveform classification task at different temperatures, and FIG. (b) showing the input, target output and fitting results of the task;
Fig. 6 is a schematic diagram of input, implementation and output of the present invention in a biorhythm simulation task. Wherein CLR of the graph (c) is an abbreviation for circadian rhythm (CIRCADIAN LOCOMOTION RHYTHM, CLR). The graph (a) is input in a multi-mode environment such as photo-thermal environment, the graph (b) is used for achieving multi-mode fusion characteristic extraction and fusion signal analysis, and the graph (c) is target output of a biological rhythm simulation task, namely the biological rhythms of the drosophila under different periodic photo-thermal combinations.
FIG. 7 is a comparison of the performance of the present invention with a conventional Multi-modal fusion algorithm, wherein MLP is an abbreviation for Multi-Layer perceptron (MLP), RNN is an abbreviation for recurrent neural network (Recurrent Neural Network, RNN), LSTM is an abbreviation for Long-Short-Term Memory (LSTM), and RC is an abbreviation for library network computation (Reservoir Computing, RC). FIG. A shows the comparison of the fitting error of the present invention with the conventional multi-modal fusion algorithm, and FIG. B shows the specific fitting waveform output of the present invention with the conventional multi-modal fusion algorithm;
In the figure: 1-a dielectric layer; 2-a substrate; 3-a source electrode; 4-a drain electrode; 5-two-dimensional nanoplatelet channel layers.
Detailed Description
Specific implementations and capabilities of the present invention are described in detail below by way of example with reference to the accompanying drawings.
The realization of the invention relies on a multi-mode fusion sensing synaptic device, the structure of the multi-mode fusion sensing synaptic device is shown in figure 1, a nano-sheet channel layer positioned on a substrate and a medium layer is a core component of the multi-mode fusion synaptic sensor for sensing external light and heat stimulus, an interface defect layer positioned between the nano-sheet channel and the medium layer is a core component for realizing short-time memory of external light and heat stimulus, and the nano-sheet channel layer is a layered bismuth oxygen selenium nano-sheet with the thickness within the range of 5-20 nm. The source drain (S/D) electrodes on two sides of the bismuth oxygen selenium nano-plate are used for collecting response current of the device reflecting external stimulus, the two-dimensional layered bismuth oxygen selenium nano-plate has sensitivity to optical and thermal environment stimulus, when the optical stimulus is applied to a bismuth oxygen selenium channel layer, light provides energy for electrons in the channel to break an original equilibrium state, and electrons are excited to transition to enter the bismuth oxygen selenium conduction band bottom, so that fermi energy level is moved upwards. Therefore, under illumination, defects of higher energy levels are filled with electrons, and when the illumination is removed, the newly filled electrons are slowly released, thereby realizing short-term memory relaxation of the illumination signal. When thermal stimulus is applied to the bismuth oxygen selenium channel layer, according to the relationship between the fermi level of the n-type heavily doped semiconductor and the temperature, the fermi level is reduced due to the temperature rise, so that electrons originally filled in the higher defect level are released at high temperature, and when the temperature is restored to the initial state, the released electrons are captured by the defect again along with the gradual rise of the fermi level, so that the short-term memory relaxation of thermal signals is realized. And because the defect of interacting with electrons under thermal stimulus is located at a deeper energy level, the memory time of the device for thermal signals is longer than that of optical signals.
The schematic diagram in the multimode bias operation mode is shown in fig. 2, the multimode library network is composed of a plurality of multimode sensing fusion synaptic devices of the same type biased by different temperatures, the optical time-varying signals applied to the global are collected by all devices simultaneously, and thus nonlinear transformation is performed by means of the dynamic characteristics of the devices in different states, and then the obtained transformation results are subjected to linear weighting to fit the target output.
FIG. 3 is a graph of current responses of a multi-modal fusion sensing synapse device for the same single light pulse at different temperatures. From the graph, under the bias of different temperatures, light pulses with the same intensity and duration are applied to the device, the channel current of the device shows significantly different dynamic responses, the relaxation time of the current response pulse is continuously shortened along with the rise of the temperature, and the photocurrent is gradually reduced. Figure 4 further discusses the nonlinearity exhibited by the response amplitude of the device as a function of the applied excitation intensity. From this graph, it can be seen that the device current response exhibits different power exponent relationships for different light intensities at different temperature biases.
The multi-mode sensing fusion synaptic device provided by the specific embodiment of the invention adopts a back gate substrate and a heavily doped silicon/hafnium oxide (p++ Si/HfO 2) substrate, the thickness of a hafnium oxide layer is within the range of 10-20nm, a source electrode and a drain electrode are composed of Ti/Au metal lamination layers, the total thickness is not more than 100nm, the thickness of a bismuth-oxygen-selenium nano-sheet of the channel layer is within the range of 5-20nm, and an interface defect layer is introduced by hydrofluoric acid wet etching.
The illumination signals are applied to the multi-modal sensing fusion synaptic devices through devices such as a single-color LED light source, a random signal generator and the like, the temperature signals are applied by using a thermoelectric system consisting of a semiconductor refrigerating sheet and a high-temperature module, and the multi-modal sensing fusion synaptic devices of the same type in the multi-modal sensing input library network are set to be biased at different temperatures.
Taking a waveform classification task as an example, a waveform u (t) to be classified consists of cosine waves and square waves, each waveform consists of 8 data points, and the output y (t) to be fitted is that the classification result represents the square waves by using a label 1, and the label 0 represents the cosine waves. The library network that accomplishes this task is 4 x 10 in size, where 10 represents the overall library network comprising 10 sub-libraries, in this task 10 sub-libraries correspond to the nonlinear responses of 2 devices biased at 5 temperatures, respectively, 20 ℃,30 ℃,40 ℃,50 ℃,60 ℃ etc., and 4 represents 4 virtual library nodes contained in each sub-library, the library nodes being obtained by multiplying the task input by a mask of length 4, which is a random combination of 0, 1.
Task inputs u (t) are applied to the devices in the form of optical signals, respectively, the devices generate photoproduction current responses with the application of illumination, and due to the short-term memory of the optical signals possessed by the devices, the current device channel current can be expressed as I (t) =i (t-1) ·αe -t/τ +f (u (t), I (t-1)), wherein u (t) represents the optical signal input at the current time t, I (t) represents the device channel current at the current time t under optical excitation, I (t-1) represents the device channel current at the time immediately before optical excitation, αe -t/τ is a memory retention factor of e exponential decay, f represents the nonlinear effect on the channel current of the input optical signal u (t) based on the channel current state at the time t-1. When the device is biased at different temperatures, the memory retention factor αe -t/τ will change with temperature because an increase in temperature provides energy for electrons to cross the defect barrier, such that the time constant τ decreases with temperature T. Meanwhile, temperature will affect the mobility of channel carriers, according to the current density formula j=qμne, where q is the single electron charge amount, μ is the carrier mobility, n is the carrier concentration, and E is the channel electric field strength, so temperature will also significantly affect the channel current I (t).
Taking the device channel current value I (t) as the library node state in the library network, the library node state will become more abundant with the addition of different temperature biases, and the 4 x 10 library nodes obtained via device current sensing will be weighted via linear weights in the linear sense layer to fit the output y (t). Fig. 5 shows the input and output results of the waveform classification task according to the embodiment of the present invention, and the response currents of the device to the waveform classification task optical input at different temperatures, as known from the response currents of the device to the waveform classification task optical input at different temperatures in fig. (a), the diversity of nonlinear transformation of the optical input signal is enriched by different temperature biases, and the task input, target output and fitting results shown in fig. (b) prove that the present invention has excellent performance in classical pattern recognition task waveform classification for library network calculation, and the error value nrmse=0.08, which is lower than all reports at present.
FIG. 6 shows a schematic diagram of a biological rhythm simulation task performed in a multi-modal fusion mode of operation using the present invention. The living beings receive the stimulation of the external environment, especially the input of the periodical fluctuation environment variables such as photo-thermal and the like, and a set of biological rhythms which synchronously change with the external environment is constructed in the living beings, so that the self-behaviors are optimally coordinated and adapted to the external environment. Similarly, the invention can accept the same light and heat multi-mode input as biology, and the fitting of the target optimal biological behavior rhythm is completed through a multi-mode sensing input library network consisting of a plurality of multi-mode fusion sensing synaptic devices of the same type.
The richness of nonlinear transformation which can be realized by the method is increased, the diversity of library network nodes is greatly expanded, the method is compared with the traditional multi-modal fusion algorithm, and the result of fig. 7 shows that the method is superior to the multi-layer perceptron and recurrent neural network with the same scale in fitting performance and slightly inferior to a long-term and short-term memory network which is far higher than the algorithm in network complexity. The method has remarkable advantages for improving the pattern recognition accuracy and the chaotic sequence prediction accuracy of the library network calculation in the time sequence signal processing.
While the invention has been described in terms of preferred embodiments, it is not intended to be limiting. Any person skilled in the art can make many possible variations and modifications to the technical solution of the present invention or modifications to equivalent embodiments using the methods and technical contents disclosed above, without departing from the scope of the technical solution of the present invention. Therefore, any simple modification, equivalent variation and modification of the above embodiments according to the technical substance of the present invention still fall within the scope of the technical solution of the present invention.
Claims (6)
1. A time sequence signal analysis method based on a parallel multi-mode sensing input library network comprises the following specific steps:
1) The multi-mode sensing input library network corresponds to nonlinear responses of a plurality of same-type multi-mode sensing fusion synaptic devices biased by different temperatures; the multi-mode sensing fusion synaptic device comprises a back gate substrate with a dielectric layer covered on the surface and a nanosheet channel layer for sensing, wherein an interface defect layer is arranged between the nanosheet channel layer and the dielectric layer, and source and drain electrodes are arranged on two sides of the nanosheet channel layer;
2) The input timing signals are respectively applied to a multi-mode sensing fusion synaptic device in the form of optical signals, the multi-mode sensing fusion synaptic device generates a photo-generated current response along with the application of illumination, the channel current of the device is expressed as I (t) =I (t-1) ·αe -t/τ +f (u (t), I (t-1)), wherein u (t) represents the optical signal input at the current time t, I (t) represents the channel current of the device at the current time t under optical excitation, I (t-1) represents the channel current of the device at the time immediately before optical excitation, αe -t/τ is a memory retention factor of e exponential decay, and f represents the nonlinear response current of the device to the current optical input based on the channel current state at the time t-1;
3) And taking the channel current value I (t) of the device as a library node state in the multi-mode sensing input library network, generating the expression of fusion characteristics of the photothermal signals by changing the channel current value in real time along with the input of two modes when illumination and temperature are changed simultaneously, and outputting a fitted time sequence signal through linear weight weighting.
2. The method for analyzing time sequence signals based on the parallel multi-mode sensing input library network according to claim 1, wherein the back gate substrate is a heavily doped silicon/hafnium oxide substrate.
3. The time sequence signal analysis method based on the parallel multi-mode sensing input library network according to claim 1, wherein the channel layer of the nano-sheet is bismuth oxygen selenium nano-sheet, and the thickness of the channel layer is in the range of 5-20 nm.
4. The method for analyzing time sequence signals based on the parallel multi-mode sensing input library network according to claim 1, wherein the source electrode and the drain electrode are composed of Ti/Au metal lamination layers, and the thickness of the Ti/Au metal lamination layers is not more than 100nm.
5. The method for analyzing time sequence signals based on the parallel multi-mode sensing input library network according to claim 1, wherein the interface defect layer is introduced by hydrofluoric acid wet etching.
6. The method for analyzing time sequence signals based on the parallel multi-mode sensing input library network according to claim 2, wherein the thickness of the hafnium oxide layer is in the range of 10-20 nm.
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