The quest to implement intelligent processing in electronic neuromorphic systems lacks methods for achieving reliable behavioral dynamics on substrates of inherently imprecise and noisy neurons. Here we report a solution to this problem that involves first mapping an unreliable hardware layer of spiking silicon neurons into an abstract computational layer composed of generic reliable subnetworks of model neurons and then composing the target behavioral dynamics as a “soft state machine” running on these reliable subnets. In the first step, the neural networks of the abstract layer are realized on the hardware substrate by mapping the neuron circuit bias voltages to the model parameters. This mapping is obtained by an automatic method in which the electronic circuit biases are calibrated against the model parameters by a series of population activity measurements. The abstract computational layer is formed by configuring neural networks as generic soft winner-take-all subnetworks that provide reliable processing by virtue of their active gain, signal restoration, and multistability. The necessary states and transitions of the desired high-level behavior are then easily embedded in the computational layer by introducing only sparse connections between some neurons of the various subnets. We demonstrate this synthesis method for a neuromorphic sensory agent that performs real-time context-dependent classification of motion patterns observed by a silicon retina

Binas, Jonathan

Chicca, Elisabetta

Neftci, Emri

Rutishauser, Ueli

Caltech Authors - Main

Supporting Information
Neftci et al. 10.1073/pnas.1212083110
SI Text
Dynamics of the Neural Soft State Machines. We observed that the
performance of the system can critically depend on the input
duration. This is especially true in the case of ambiguous situations
occurring when one input can induce a transition from both the
current and the next state. If an input signal is too long, multiple
transitionsmay occur; if it is too short, it may not be able to initiate
a transition at all. The steady-state analysis of the system cannot
account for this effect. To counter this problem and derive an
adequate input duration, we consider the temporal dynamics of
the system.
Assuming that only two state populations are active during
a transition and all others are silent, we can reduce the system to
N = 2 states S1 and S2 with transitions S1!a S2 and S2!a S1. We
show that as long as the input a is applied, the activity oscillates
between these two states. Half the period of this oscillation
constitutes an adequate input duration. In the linear threshold
unit (LTU) approximation, the dynamics of the two-state system
are described by the set of equations
τE _x1 = − x1 + σðwEx1 −wIExI +ϕ1z2 −TEÞ ;
τE _x2 = − x2 + σðwEx2 −wIExI +ϕ1z1 −TEÞ ;
τI _xI = − xI + σðwEIðx1 + x2Þ−TIÞ ;
τE _z1 = − z1 + σðwETz1 −wIEzI +ϕ2x1 −TE + binÞ  ;
τE _z2 = − z2 + σðwETz2 −wIEzI +ϕ2x2 −TE + binÞ  ;
τI _zI = − zI + σðwEIðz1 + z2Þ−TIÞ  ;
where x1;2 and z1;2 are the state and transition populations, re-
spectively, xI and zI are the inhibiting populations of the respec-
tive sWTAs, and wE = α+ γ.
Assuming that all units are active at any time, we can identify
the nonlinearity σ with the identity function. Using the sub-
stitutions x+ = x1 + x2, x− = x1 − x2, z+ = z1 + z2, and z− = z1 − z2, we
can decouple the equations and obtain two independent systems,
τE _x+ = − x+ +wEx+ − 2wIExI +ϕ1z+ − 2TE  ;
τE _z+ = − z+ +wETz+ − 2wIEzI +ϕ2x+ − 2TE + 2bin  ;
τI _xI = − xI +wEIx+ −TI  ;
τI _zI = − zI +wEIz+ −TI  ;
and
τE _x− = − x− +wEx− −ϕ1z−  ;
τE _z− = − z− +wETz− +ϕ2x−  :
For the parameters from Table S1 and τi < τe the first system has
a stable fixed point limt→∞ðx+; z+; xI ; zIÞ= ðx∞+ ; z∞+ ; x∞I ; z∞I Þ. Thus,
for t  0, the dynamics are governed by the second system,
which has an unstable fixed point at ð0; 0Þ. The system can be
solved and, for the parameters from Table S1, yields a solution
x−ðtÞ= x0e
wE+wET
2τe
t sin
 ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
4ϕ1ϕ2 − ðwE −wETÞ2
q
2τe
t+ ρ
!
;
where x0 and ρ are constants.
The oscillating part of the solution reflects the oscillation of the
system between the two states S1 and S2 and leads to a transition
duration, i.e., the time taken by the state-holding population to
rise from zero to peak activity, of
ttrans =
2πτeffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
4ϕ1ϕ2 − ðwE −wETÞ2
q :
The cyclic two-state soft state machine (SSM) described here has
been simulated both spike based and as a system of LTUs with the
parameters displayed in Table S1. The spiking system contained
150 neurons per population and the connection probabilities were
multiplied by a factor of 16=150 to reflect the overall connection
strength used in our hardware experiments. The larger number
of neurons reduced the activity fluctuations and allowed a clearer
readout of the transition frequency. As shown in Fig. S2, the
analytic result is in good agreement with the simulations. For
the parameters from Table S1 and a time constant τE = 50 ms
the estimated transition duration equals ttrans = 305 ms, which is
in the scope of the value used in our experiments.
Nullcline Analysis for the Calculation of bmin. Here, we explicitly
compute the input bmin necessary to perform a transition from
state pre to state post. The equations describing the dynamics of
pre and post are
τE _xpre + xpre = σ

wExpre −wIEwEI

xpre + xpost

+ c

;
τE _xpost + xpost = σ

wExpost −wIEwEI

xpre + xpost

+ c+ b

:
To calculate bmin, we study the stability of the fixed points in this
system, using a phase plane analysis. The nullclines of this system
are the curves defined by _xpost = 0 and _xpre = 0:
8<
:xpost; xpre xpost =
8<
:
−wEIwIExpre + c+ b
Λ
; if   xpre <
c+ b
wEIwIE
;
0; otherwise;
9=
;
8<
:xpost; xpre xpre =
8<
:
−wEIwIExpost + c
Λ
; if xpost <
c
wEIwIE
;
0; otherwise:
9=
;:
These curves are illustrated in Fig. S4, where c= ðwIETI −TEÞ.
The arrows in Fig. S4 indicate the direction of the gradient at
both sides of the nullclines. By definition of the nullcline, the
direction of the gradient vector does not change within either
side of the nullcline. This analysis provides a visual and intuitive
indication on the stability associated with the fixed points (situ-
ated at the crossings of the nullclines). If both vectors point to-
ward the fixed point, then it is stable. In any other case the fixed
point is unstable. We observe that the fixed points on the axes
are stable, whereas the fixed point in the middle is unstable.
The effect of an input b> 0 to post is to shift the linear portion
of the nullcline toward the right. According to Fig. S4, when the
input reaches a critical magnitude, the central fixed point (which
is unstable) merges with the fixed point associated with pre being
active, which then loses stability. The only stable fixed point of
the system becomes the one associated with post. A simple cal-
culation shows that an input bmin = c
wIEwEI
Λ − 1

suffices.
Neftci et al. www.pnas.org/cgi/content/short/1212083110 1 of 4
List of Parameters. The parameters displayed below were mea-
sured once the parameter calibration procedure described in ref.
1 was completed. The measurements of the synaptic efficacies
were carried out as explained in ref. 1. The inhibitory couplings
were the same for both transitions soft winner-take-all (sWTA)
and state-holding sWTA. Our choice of parameters is not opti-
mal with respect to stability and performance because of hard-
ware constraints, namely in the number of available synapses and
leak currents. Because the leak is a global parameter, state-
holding units and transition units were forced to share TE. Due to
constraints in the number of independent synapse parameters,
the connection probabilities ranged from 20% to 100%. How-
ever, the neural model allows much smaller probabilities [e.g.,
around 10% (2)] and this could be easily achieved in hardware as
well by introducing a larger number of independent synapse
parameters.
1. Neftci E, Chicca E, Indiveri G, Douglas R (2011) A systematic method for configuring
VLSI networks of spiking neurons. Neural Comput 23(10):2457–2497.
2. Brunel N (2000) Dynamics of sparsely connected networks of excitatory and inhibitory
spiking neurons. J Comput Neurosci 8(3):183–208.
Fig. S1. Signal restoration in the sWTA and coexistence of digital selection and analog amplification. We simulate a network of integrate-and-fire (I&F)
neurons to demonstrate the signal restoration property of the sWTA, using the same parameters as in the state-holding sWTA populations (Table S1). In
addition to the sWTA couplings, there are recurrent connections between neurons 24 and 40. (A) Raster plot of a trial run (Lower) and firing rate of neurons
24 −  40 (Upper). The sWTA is stimulated by a box-shaped signal corrupted by noise, from 0 s to 1:5 s (black). (B) Mean firing rates of the stimulus and network
activity. After an initial transient, the feedback in the network amplifies the signal and restores it toward the stored pattern (blue, 0:5−1:5 s). The resulting
activity still reflects the stimulus profile, but after the stimulus is removed, the activity persists and is shaped only by the pattern stored in the couplings (green,
1.5–2 s). The circuit thus interprets an incomplete or noisy input signal by restoring it toward the pattern embedded in its connections. During times 2  −  4 s, all
of the excitatory neurons are stimulated by an oscillatory signal (red, 2  −  3 s, 2 Hz; 3 −  4 s, 4 Hz), and the activity in the sWTA reflects this analog signal in the
active attractor state only (neurons 24–40; the other neurons are inhibited). This illustrates the coexistence of digital selection (the active pattern) and the
analog signal amplification properties of the sWTA (1). The memory is analog in the sense that the attractor can modulate its activity to reflect spatial and
temporal changes in its inputs. These are well-known properties of attractor networks; see, e.g., ref. 2. In the plots, the firing rates of the stimuli were
multiplied by the input synapse weight (0.015) and subtracted by Texc to emphasize the effect of the recurrent connections. In addition to the parameters in
Table S1, we used τexc = 80 ms, τinh = 50 ms.
1. Hahnloser R, Sarpeshkar R, Mahowald MA, Douglas RJ, Seung S (2000) Digital selection and analog amplification co-exist in an electronic circuit inspired by neocortex. Nature
405(6789):947–951.
2. Amit DJ, Brunel N (1997) Dynamics of a recurrent network of spiking neurons before and following learning. Network 8(4):373–404.
Neftci et al. www.pnas.org/cgi/content/short/1212083110 2 of 4
Fig. S2. Oscillations in the cyclic SSM configuration. The cyclic two-state SSM has been simulated both spike based (as a system of I&F neurons) and as a system
of LTUs. Shown are the spiking activity of the two state populations (Top), the mean firing rates of the same populations (Middle; bin size 10 ms), and the rates
in the LTU approximation (Bottom). The activity of the two state populations is plotted in black and blue. The oscillating part of the analytic solution is shown
as a red, dotted line.
Fig. S3. Activity of the transition sWTA in the pattern recognition task. This raster plot presents the spiking activity of the transition populations in the trial
presented in Fig. 4. Each population represents one possible transition (an arrow in the state diagram, Fig. S1). The selective attention chip (SAC) stimulates
a group of transition populations receptive to the location of the active neuron. The population previously stimulated by an active state wins the competition
and drives the transition to a new state. The spatial variability observed in the spiking responses is mostly due to fabrication mismatch.
Neftci et al. www.pnas.org/cgi/content/short/1212083110 3 of 4
Fig. S4. Phase plane analysis of state transition and calculation of bmin. The nonlinear system has three fixed points that are situated at the crossings of the
two nullclines (red and blue). The black arrows indicate the direction of the gradient at both sides of the nullclines. The central fixed point is always unstable
but the two other fixed points situated on the axes can be stable. Applying an input to post shifts its nullcline to the right (red dashed line). The analysis
illustrates that, if the input b is larger than bminΛ , the fixed point situated on the horizontal axis

xpre = cΛ

loses stability. This provides us with the minimum input
required to induce transition from pre to post.
Fig. S5. Total monitored and mapped address-event representation (AER) activity in an example SSM. We measure the AER communication in a randomly
generated SSM of dimensions Ns = 5, Nq = 5, without ambiguous transitions. (A) Number of mapped (routed) address events per second, corresponding to the
AER traffic. The positions of the peaks correspond to the times when the inputs were provided. (B) Number of monitored address events, corresponding to
neurons that have spiked.
Table S1. Parameters used for the soft state machine
Parameter Value Description
α 0.94 Weight of recurrent excitative couplings within state-holding sWTA
wET 0.74 Weight of recurrent excitative couplings in transition sWTA
wEI 0.47 Weight of excitative couplings from excitatory to inhibitory neurons
wIE 6.06 Weight of inhibitive couplings from inhibitory to excitatory neurons
γ 0.68 Weight of recurrent excitative couplings between state-holding sWTAs
ϕ1 0.21 Weight of excitative coupling from old state to transition populations
ϕ2 2.18 Weight of excitative coupling from transition population to new state
pα 0.7 Connection probability of α couplings
pET 0.55 Connection probability of wET couplings
pEI 0.5 Connection probability of wEI couplings
pIE 0.5 Connection probability of wIE couplings
pγ 0.8 Connection probability of γ couplings
pϕ1 0.25 Connection probability of ϕ1 couplings
pϕ2 1.0 Connection probability of ϕ2 couplings
TE 7 Hz Excitatory neuron threshold
TI 11 Hz Inhibitory neuron threshold
bin 15.94 Hz Firing rate of external input to transition population, weighted by input synapse
bmin 29.21 Hz Minimum firing rate of input to state population needed to initiate transition
Neftci et al. www.pnas.org/cgi/content/short/1212083110 4 of 4


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Synthesizing cognition in neuromorphic electronic systems

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Synthesizing cognition in neuromorphic electronic systems

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