Spiking Neural Networks (SNNs) can unleash the full power of analog Resistive Random Access Memories (RRAMs) based circuits for low power signal processing. Their inherent computational sparsity naturally results in energy efficiency benefits. The main challenge implementing robust SNNs is the intrinsic variability (heterogeneity) of both analog CMOS circuits and RRAM technology. In this work, we assessed the performance and variability of RRAM-based neuromorphic circuits that were designed and fabricated using a 130 nm technology node. Based on these results, we propose a Neuromorphic Hardware Calibrated (NHC) SNN, where the learning circuits are calibrated on the measured data. We show that by taking into account the measured heterogeneity characteristics in the off-chip learning phase, the NHC SNN self-corrects its hardware non-idealities and learns to solve benchmark tasks with high accuracy. This work demonstrates how to cope with the heterogeneity of neurons and synapses for increasing classification accuracy in temporal tasks

Andrieu, F

Brivio, S

Castellani, N

Dalgaty, T

Esmanhotto, E

Hirtzlin, T

Indiveri, G

Molas, G

Moro, Filippo

Payvand, M

Spiga, S

Trabelsi, A

Vianello, E

English

arXiv

ZORA

Zurich Open Repository andArchiveUniversity of ZurichUniversity LibraryStrickhofstrasse 39CH-8057 Zurichwww.zora.uzh.chYear: 2022Hardware calibrated learning to compensate heterogeneity in analog RRAM-basedSpiking Neural NetworksMoro, Filippo ; Esmanhotto, E ; Hirtzlin, T ; Castellani, N ; Trabelsi, A ; Dalgaty, T ; Molas, G ; Andrieu, F ;Brivio, S ; Spiga, S ; Indiveri, G ; Payvand, M ; Vianello, EAbstract: Spiking Neural Networks (SNNs) can unleash the full power of analog Resistive Random Access Mem-ories (RRAMs) based circuits for low power signal processing. Their inherent computational sparsity naturallyresults in energy efficiency benefits. The main challenge implementing robust SNNs is the intrinsic variability(heterogeneity) of both analog CMOS circuits and RRAM technology. In this work, we assessed the performanceand variability of RRAM-based neuromorphic circuits that were designed and fabricated using a 130 nm tech-nology node. Based on these results, we propose a Neuromorphic Hardware Calibrated (NHC) SNN, where thelearning circuits are calibrated on the measured data. We show that by taking into account the measured hetero-geneity characteristics in the off-chip learning phase, the NHC SNN self-corrects its hardware non-idealities andlearns to solve benchmark tasks with high accuracy. This work demonstrates how to cope with the heterogeneityof neurons and synapses for increasing classification accuracy in temporal tasks.DOI: https://doi.org/10.1109/iscas48785.2022.9937820Posted at the Zurich Open Repository and Archive, University of ZurichZORA URL: https://doi.org/10.5167/uzh-231223Conference or Workshop ItemAccepted VersionOriginally published at:Moro, Filippo; Esmanhotto, E; Hirtzlin, T; Castellani, N; Trabelsi, A; Dalgaty, T; Molas, G; Andrieu, F; Brivio, S;Spiga, S; Indiveri, G; Payvand, M; Vianello, E (2022). Hardware calibrated learning to compensate heterogeneity inanalog RRAM-based Spiking Neural Networks. In: 2022 IEEE International Symposium on Circuits and Systems(ISCAS), Austin, TX, USA, 27 May 2022 - 1 June 2022, IEEE.DOI: https://doi.org/10.1109/iscas48785.2022.9937820Hardware calibrated learning to compensateheterogeneity in analog RRAM-based SpikingNeural NetworksFilippo Moro1, E. Esmanhotto1, T. Hirtzlin1, N. Castellani1, A. Trabelsi1, T. Dalgaty1, G. Molas1,F. Andrieu1, S. Brivio2, S. Spiga2, G. Indiveri3, M. Payvand3, and E. Vianello11 CEA-Leti, Grenoble, France, 2 CNR-IMM, Agrate Brianza, Italy3 Institute of Neuroinformatics, University of Zurich and ETH Zurich, SwitzerlandAbstract—Spiking Neural Networks (SNNs) can unleash thefull power of analog Resistive Random Access Memories(RRAMs) based circuits for low power signal processing. Theirinherent computational sparsity naturally results in energy effi-ciency benefits. The main challenge implementing robust SNNsis the intrinsic variability (heterogeneity) of both analog CMOScircuits and RRAM technology. In this work, we assessed the per-formance and variability of RRAM-based neuromorphic circuitsthat were designed and fabricated using a 130 nm technologynode. Based on these results, we propose a NeuromorphicHardware Calibrated (NHC) SNN, where the learning circuitsare calibrated on the measured data. We show that by takinginto account the measured heterogeneity characteristics in the off-chip learning phase, the NHC SNN self-corrects its hardware non-idealities and learns to solve benchmark tasks with high accuracy.This work demonstrates how to cope with the heterogeneity ofneurons and synapses for increasing classification accuracy intemporal tasks.I. INTRODUCTIONResistive Random Access Memories (RRAMs) have beenshown to have a large potential for locally storing the synapticweights and enabling “in memory computing” in ArtificialNeural Networks (ANNs) [1]. The assembly of resistivememories organized as a crossbar naturally implements theMultiply And Accumulate (MAC) operation in ANNs (Fig. 1).However, one of the major problems of this ANN approachis network scalability. In this approach, the output current ateach column, and the overall power budget increase linearlywith the number of devices being read (i.e. number of ac-tivated rows), thus strongly limiting the array size (Fig. 1).Another limitation is the overhead required by the Digital-to-Analog (DAC) and Analog-to-Digital (ADC) circuits neededfor the conversion. To overcome these issues we focus on thehardware implementation of analog Spiking Neural Networks(SNNs). SNNs have typically very sparse activations, so thenumber of activated rows at any instance of time is very small,significantly reducing the current and power consumption ateach column (Fig. 1). Moreover, analog neurons and synapsesin SNNs do not require DACs and ADCs, resulting in a furtherreduction of energy consumption and area [2].The basic building block of analog SNNs is composedof Leaky Integrate and Fire (LIF) neurons. In SNNs LIFneurons transmit voltage pulses (spikes) to multiple columns ofone resistor-one-transistor (1T1R) devices, which encode thenetwork synaptic weights in their conductance. The resultingcurrent is the weighted sum of all the synaptic outputs. Inthe architecture we propose these currents are then integratedtemporally by a shared Differential Pair Integrator (DPI)circuit (Fig. 1), which is a subthreshold log-domain low-passfilter [3], [4]. To realize a multi-layer neural network, suchbasic blocks can be chained together in a modular way.However, both analog circuits and RRAMs exhibit devicevariability. In this work, we compared the performance ofSNNs trained to carry out three different tasks, with differ-ent degrees of hardware heterogeneity. The CMOS variabil-ity affects the neuron’s and synapse’s time constants. TheRRAM variability affects the synaptic weights. We propose aNeuromorphic Hardware Calibrated (NHC) SNN, where off-chip training is calibrated on experimentally measured dataand hardware non-idealities. This approach allows achievingclassification accuracy on three different tasks, comparable toequivalent full-precision (32-bit floating point) software-basedsimulations. Moreover, we demonstrated that heterogeneity inneuron and synapse time constants originates a richer systemtemporal dynamics, thus improving the accuracy for taskswith temporal structure. Experiments have been conducted oncustom analog LIF neuron and DPI synapse circuits as wellas on a 4 kb HfO2 crossbar 1T1R memory array fabricated ina commercial 130 nm technology node.II. HETEROGENEITY IN NEURONS AND SYNAPSESWe designed, fabricated, and tested analog CMOS-basedLIF neuron and synapse circuits (Fig. 2a,b). The design isbased on the DPI circuit [3], [4], which implements a low passfilter with time constant controlled by a tunable bias voltage.In arrays of such circuits the same bias voltage producesheterogeneous leak current. To derive the DPI circuit timeconstant we applied an input voltage pulse at the input (Vin)and measured the voltage at the capacitor. The resulting tracewas fitted with an exponential function. By modulating the Vlkbias of the neuron (or Vtau biase of the synapse), we modifiedthe current leak rate, resulting in different time constants(Fig. 2c). The measurements have been repeated over 100samples and the time constant extrapolated from the responseof Vmem/Vsyn. Variability in the neuron and synapse timeconstants is quantified at about 30% in standard deviation overthe mean.arXiv:2202.05094v1  [cs.NE]  10 Feb 2022Fig. 1: RRAM crossbar arrays in ANN (a) and SNN (b). (c)Quantification of current magnitude per column for differentaverage RRAM conductance and row activation frequencydistribution for ANN and SNN.III. VARIABILITY IN THE RRAM AND SYNAPTIC WEIGHTSTo obtain 8 conductance levels per RRAM device in a4 kb 1T1R array, we used the multilevel smart program-ming procedure described in [5]. We then measured andcharacterized the distribution of the conductances in time(see Fig. 3a). As shown, the smart programming procedureyields tightly distributed conductance levels, which broadenwith time due to temporal variability of the devices. RRAMsshow 3 degrees of temporal variability that take place atdifferent time scales (Fig. 3b). Relaxation takes place just afterprogramming (milliseconds) and broadens all the conductancelevels distributions. Data retention causes long term (hours)variation of the conductance, particularly affecting the lowerconductance levels, whose mean of the distribution decreaseswith time (Fig. 3c). Read-to-Read (R2R) noise does not affectthe shape of the conductance distribution, although whenlooking at individual devices there are fast temporal fluctua-tions of conductance due to reading disturbances and RandomTelegraph Noise (RTN). We evaluate the RTN component inR2R via the ∆G/G figure of merit (Fig. 3d), measuring theconductance jumps ∆G due to RTN. The result is in line withthe literature [6]. Finally, the Power Spectral Density of the 8conductance levels shows that the amount of noise is inverselyproportional to the conductance and is general of the 1/f type(Fig. 3e), as also observed in [7].Fig. 2: LIF neuron (a) and DPI-RRAM synapse (b) circuits.(c) Time constants in the neuron and synapse circuits as afunction of the biase leak voltage.IV. HARDWARE-CALIBRATED OFF-CHIP LEARNINGWe trained the SNN off-chip with the Surrogate Gradi-ent algorithm [8], using 32-bits floating point weights: thistechnique allows to take into account the non-idealities ofthe hardware substrate in the learning phase. Heterogeneity isintroduced by assigning each neuron and synapse a differenttime constant value sampled from the experimental distribu-tions of Fig. 2c. The procedure is completed by transferringthe learned weights to the RRAM array, by discretizing themto 3-bit values and converting them to the correspondingconductance levels. As the training accounts for the variabilityof both analog circuits and RRAM devices, we defined it asNeuromorphic Hardware Calibrated (NHC) procedure. Thisprocedure is applied to three different benchmark tasks withdifferent degrees of temporal structure: MNIST (static visualimage of handwritten digits), ECG [9] (heart arrhythmiaclassification), and SHD [10] (spoken digits). In all the casesthe architecture of the network features 128 neurons in thehidden layer, with recurrent connections enabled for the ECGand SHD tasks. Input and Output layer dimensions depend onthe task. For the ECG case, the 5 most frequent heart diseasesin the dataset are selected for classification.V. IMPACT OF HETEROGENEITY ON PERFORMANCEIn Table I we list the effect of the measured analog circuitsheterogeneity on the performance of the network, comparedto the case of ideal SNNs (Homogeneous SNN) and software-based ANNs. Ignoring hardware heterogeneity in the trainingphase (Non-Calibrated SNN) and then performing inference ona heterogeneous hardware network causes the accuracy of theSNN to drop by more than 10%. The proposed NHC trainingFig. 3: (a) Multilevel programming of 8 conductance levelsat t=0 s and t=60 s. (b) Temporal variability effects afterprogramming. (c) Level distribution mean, measured overtime. (d) Measured ∆G/G as a function of the programmingcurrent (∆G is due to RTN and is defined in (b)). (e) PowerSpectral density of the noise in the 8 conductance levels.approach recovers this loss in performances. Moreover, hetero-geneity in time constants surprisingly improves the accuracyon datasets with rich temporal structure (ECG and SHD). Thisresult is in agreement with the theoretical study performed in[11] and could be explained by the richer temporal dynamicsof the heterogeneous substrate.Weights N-MNIST ECG SHDANN float32 97.5% 95.5% 89.0%NC SNN float32 90.2% 63.7% 58.4%Hom. SNNfloat32 97.4% 94.5% 72.5%4bits 96.7% 91.4% 71.6%NHC SNNfloat32 97.5% 94.9% 74.9%4bits 96.9% 91.4% 73.2%RRAM t=0s 96.8% 91.2% 71.2%RRAM t=5s 96.2% 90.2% 67.5%RRAM t=1h 95.3% 89.9% 60.4%TABLE I: NHC SNN results and comparison with ANN, Non-Calibrated SNN (NC SNN) and Homogenous SNN (Hom.SNN).VI. IMPACT OF RRAM NON-IDEALITIES ONPERFORMANCEThe RRAMs support up to 8 distinct conductance levels,enough to saturate performance for simple datasets, as demon-strated in [5]. The impact of the RRAM temporal variabilityFig. 4: Accuracy for the three benchmark tasks, tested with theRRAM array measured across time. (a) Data Retention actsover the course of hours, reducing accuracy. (b) Relaxationinduces an accuracy drop after programming. (c) R2R causessmall variations of conductance each time RRAM are read,slightly perturbing performance.is shown in Fig 4. Relaxation causes an immediate decrease inperformance (Fig 4b). The decrease of performance over timedue to poor data retention (Fig 4a) is minimal for simpler taskslike MNIST (blue) and ECG (red), while it is more pronouncedfor SHD (green). R2R noise slightly varies the conductancevalues at each inference operation (Fig 4c), causing accuracyto fluctuate. Furthermore, the impact of failures in the RRAM-based neuromorphic chip is evaluated. A failure is representedby a device stuck at either low (1µS ± 0.5µS) or high(200µS ± 25µS) conductance. The accuracy as a functionof the RRAM’s Bit Error Rate (BER) is shown in Fig 5a:SNN models are resilient up to BER of 10−3. In order tomitigate faults, we can retrain the SNN with broken RRAMs(Fig 5b), to recover performance. MNIST is re-learned withjust one learning epoch, while ECG and SHD require a fewmore epochs to recover. Overall, the performance is almostfully restored in all cases.VII. ENERGY ASSESSMENTTo assess the efficiency of an RRAM based neuromorphicprocessor we compare their energy per inference sample with amixed-signal neuromorphic processor, DYNAP [12]. DYNAPuses similar LIF neuron and DPI synapse circuits, but employsan asynchronous digital communication protocol to implementnetwork connectivity. The energy consumption for the RRAM-based system is estimated by means of SPICE simulations andFig. 5: Analysis of performance with RRAM failures and re-training taking the failures into account. (a) Accuracy as afunction of the Bit-Error-Rate (BER) of RRAM weights. (b)Networks with high degree of RRAM failures (BER or 10−2)re-trained considering the weight defects.is more than 1 order of magnitude lower than that of DYNAP(Fig. 6a). Energy is dominated by the RRAMs (that storethe synaptic weights and define the network topology) in thereading operation. However, the RRAM associated energy isabout 1 order of magnitude less than that of the communicationprotocol used in DYNAP (Fig. 6b). Furthermore, SNN compu-tation is very sparse, reducing the number of simultaneouslyactivated rows of the RRAM array, yielding small currents onthe column lines (Fig. 6c).VIII. CONCLUSIONWe proposed a new approach for training RRAM-basedanalog SNN that takes into account the hardware details. Theresults show, that SNNs trained with our approach reach com-petitive classification accuracy levels, and that the heterogene-ity of neurons and synapses improves network performancefor temporal tasks. Although the use of RRAMs could resultin slightly reduced performance over time, they can reducethe energy cost per inference by one order of magnitude withrespect to conventional Mixed-Signal processors.ACKNOWLEDGMENTThis work is supported by the H2020 MeM-Scales project(871371) and the ANR Carnot funding.REFERENCES[1] A. Sebastian, M. Le Gallo, R. Khaddam-Aljameh, and E. Eleftheriou,“Memory devices and applications for in-memory computing,” NatureNanotechnologies, vol. 15, pp. 529–544, 2020.[2] A. Valentian, F. Rummens, E. Vianello, T. Mesquida, C. L.-M. de Bois-sac, O. Bichler, and C. Reita, “Fully integrated spiking neural networkwith analog neurons and rram synapses,” in 2019 IEEE InternationalElectron Devices Meeting (IEDM), 2019, pp. 14.3.1–14.3.4.Fig. 6: (a) Energy per inference step of RRAM-based SNN,compared to DYNAP [12]. (b) Energy contributions of theRRAMs and analog circuit (DPI-LIF), for the MNIST bench-mark, compared to the routing in DYNAP. (c) Row accessstatistics show the sparse computation features of the SNN.[3] P. Livi and G. Indiveri, “A current-mode conductance-based siliconneuron for address-event neuromorphic systems,” in 2009 IEEE Inter-national Symposium on Circuits and Systems, 2009, pp. 2898–2901.[4] C. Bartolozzi and G. 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Hardware calibrated learning to compensate heterogeneity in analog RRAM-based Spiking Neural Networks

Hardware calibrated learning to compensate heterogeneity in analog RRAM-based Spiking Neural Networks

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