Neural Noise Can Explain Expansive, Power-Law Nonlinearities in Neural Response Functions

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Neural Noise Can Explain Expansive, Power-Law Nonlinearities in Neural Response Functions

Kenneth D. Miller¹ and Todd W. Troyer²

¹Departments of Physiology and Otolaryngology, W. M. Keck Center for Integrative Neuroscience, Sloan Center for Theoretical Neurobiology, University of California, San Francisco, California 94143-0444; and ²Department of Psychology, Neuroscience and Cognitive Science Program, University of Maryland, College Park, Maryland 20742

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
APPENDIX A
APPENDIX B
REFERENCES

Miller, Kenneth D. and Todd W. Troyer. Neural Noise Can Explain Expansive, Power-Law Nonlinearities in Neural Response Functions. J. Neurophysiol. 87: 653-659, 2002. Many phenomenological models of the responses of simple cells in primary visual cortex have concluded that a cell's firingrate should be given by its input raised to a power greater thanone. This is known as an expansive power-law nonlinearity. However,intracellular recordings have shown that a different nonlinearity,a linear-threshold function, appears to give a good predictionof firing rate from a cell's low-pass-filtered voltage response.Using a model based on a linear-threshold function, Anderson etal. showed that voltage noise was critical to converting voltageresponses with contrast-invariant orientation tuning into spikingresponses with contrast-invariant tuning. We present two separateresults clarifying the connection between noise-smoothed linear-thresholdfunctions and power-law nonlinearities. First, we prove analyticallythat a power-law nonlinearity is the only input-output functionthat converts contrast-invariant input tuning into contrast-invariantspike tuning. Second, we examine simulations of a simple modelthat assumes instantaneous spike rate is given by a linear-thresholdfunction of voltage and voltage responses include significantnoise. We show that the resulting average spike rate is well describedby an expansive power law of the average voltage (averaged overmultiple trials), provided that average voltage remains less thanabout 1.5 SDs of the noise above threshold. Finally, we use thismodel to show that the noise levels recorded by Anderson et al.are consistent with the degree to which the orientation tuningof spiking responses is more sharply tuned relative to the orientationtuning of voltage responses. Thus neuronal noise can robustlygenerate power-law input-output functions of the form frequentlypostulated for simplecells.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION APPENDIX A APPENDIX B REFERENCES

Responses of visual cortical simple cells are commonly described by simple phenomenological models in which a linear filteringof the stimulus is followed by an expansive power-law nonlinearityto determine an instantaneous firing rate (Albrecht and Geisler1991; Albrecht and Hamilton 1982; Anzai et al. 1999; Carandiniet al. 1997, 1999; Emerson et al. 1989; Gardner et al. 1999; Heeger1992, 1993; Murthy et al. 1998; Sclar et al. 1990). By a power-lawnonlinearity, we mean that a cell's firing rate r depends on itsinput or voltage V as r = k([V]⁺)ⁿ for constants k and n, where the 0 voltage is set equal to themean voltage at rest and [V]⁺ = max (V, 0).¹ By an expansive nonlinearity, we mean that n > 1. The linearfiltering aspect of this model receives support from a numberof studies showing that voltage responses of simple cells areremarkably linear functions of the visual stimulus (Anderson etal. 2000; Jagadeesh et al. 1993, 1997; Lampl et al. 2001) (butsee DISCUSSION).

Despite the success of using an expansive power law nonlinearity in phenomenological models, direct experimental investigationshave shown that the transformation from instantaneous voltageto instantaneous spike rate is well approximated by a linear-thresholdfunction r = k([V $-$ T]⁺), where V is the voltage after removal of spikes and low-passfiltering, r is the low-pass-filtered spike train, and T is aneffective spike threshold (Anderson et al. 2000; Carandini andFerster 2000). In this paper, we show a simple and surprisinglyrobust connection between linear-threshold models and expansivepower-law nonlinearities: if the voltage trace includes significantstimulus-independent noise and if the conversion from instantaneousvoltage to instantaneous firing rate is a linear threshold function,then the conversion from trial-averaged voltage to trial-averagedfiring rate will be well described by an expansive power law (cf.Suarez and Koch 1989).

This work is inspired by the recent results of Anderson et al. (2000). They studied the intracellular basis for the observationthat orientation tuning of visual cortical neurons is contrastinvariant, i.e., changing stimulus contrast simply scales themagnitude of a neuron's response, without changing the shape ofits orientation tuning curve (Sclar and Freeman 1982; Skottunet al. 1987). Anderson et al. (2000)'s results can be separatedinto three main findings. First, they found that a cell's trial-averagedvoltage response showed contrast-invariant orientation tuning(both the size of the mean voltage response and the amplitudeof voltage modulation had this property). Second, they found thatspiking responses also showed contrast-invariant tuning (as expected)and that a given neuron's spiking response was more narrowly tunedfor orientation than its intracellular voltage response. Finally,they used computer simulations to demonstrate that a linear thresholdmodel for converting instantaneous voltage to instantaneous spikerate could account for this data, but that the noise in the actualvoltage traces was critical for this result: if a linear thresholdmodel was applied to the actual noisy voltage traces, or to thetrial-averaged voltage traces with the addition of random noise,then contrast-invariant spiking tuning was attained; but if alinear threshold model was simply applied to the trial-averagedvoltage traces without additional noise, the spiking tuning becamecontrastdependent.

Here we present two basic results that serve to clarify the connection between the work of Anderson et al. (2000) and themany successful phenomenological descriptions of simple cell responsesthat assume linear input plus an expansive power law nonlinearity.First, while others have noted that a power law nonlinearity convertscontrast-invariant input into contrast-invariant output (e.g.,Carandini et al. 1997; Heeger 1992; Heeger et al. 1996), herewe prove that a power law is the only function that achieves this.This result, in combination with the results of Anderson et al.(2000), implies that adding noise to a linear threshold functionmust yield power law behavior to a good approximation. Second,we quantify the degree to which a noise-smoothed linear thresholdfunction can indeed be approximated by a power law, finding thatthe approximation holds over a wide range of parameters. We alsoshow that the exponent in the best-fit power law decreases withincreasing noise level and that the sizes of signal and noisemeasured by Anderson et al. (2000) predict an exponent that accountswell for the observed sharpening of spiking orientation tuningrelative to voltagetuning.

	RESULTS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION APPENDIX A APPENDIX B REFERENCES

Contrast-invariant tuning

A response function is contrast invariant if changes in stimulus contrast simply scale responses without affecting the tuningto other parameters. For example, let V(c, $theta$ ) describe the voltageresponse of a given neuron as a function of contrast level c andorientation $theta$ . Let g_V( $theta$ ) be the orientation tuning function atmaximal contrast. If the cell displays contrast-invariant orientationtuning, then changing to a different contrast c simply scalesthe response, i.e., V(c, $theta$ ) = f_V(c)g_V( $theta$ ), where f_V(c) is the cell'scontrast response function (Fig. 1). Therefore saying that orientationtuning is contrast invariant is equivalent to saying that thecontrast response function is orientation invariant.

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Fig. 1. Illustration of a response function with contrast-invariant orientation tuning. Vertical axis shows response R(c, $theta$ ) to contrast c and orientation $theta$ . The response separates into the product of a function of contrast times a function of orientation, R(c, $theta$ ) = f(c)g( $theta$ ). This condition ensures that orientation tuning is simply scaled by changes in contrast as illustrated by the projections along the orientation axis for different contrasts. This also implies that contrast tuning is simply scaled by changes in orientation as illustrated by the projections along the contrast axis for different orientations.

We will work in units in which V = 0 represents the mean voltage at rest, in the absence of a stimulus, so that V representsthe stimulus-induced voltage. It is easy to see that if the voltageresponse is contrast invariant, and the stimulus-induced spikerate R(V) (i.e., the spike rate after subtracting off the backgroundrate) is equal to the stimulus-induced voltage raised to a powern, then this spike rate is contrast invariant:

(1)

(In the last step, we used the fact that the contrast response function is nonnegative.) In APPENDIX A, we provethe converse, i.e., a power law is the only function that transformscontrast-invariant inputs into contrast-invariant spikingresponses.

Only a pure power law yields contrast invariant responses. Power law functions with nonzero threshold, i.e., r(V) = k([V $-$ T]⁺)ⁿ for T > 0, do not yield contrast-invariant responses, insteadthey typically lead to an "iceberg" effect $---$ tuning widens withincreasing contrast as more orientations receive suprathresholdinput.

Accuracy of power-law approximation

Now we turn to the question of whether noise-smoothed threshold linear functions can be approximated by power-law nonlinearities.We let the instantaneous spike rate r be a threshold linear functionof voltage V: r_T(V) = k[V $-$ T]⁺, where T > 0 is a threshold and again V = 0 represents the meanvoltage at rest. We assume that the voltage can be written asa sum of a trial-averaged voltage $V$ and zero-mean Gaussian noise $upsilon$ with SD $sigma$ : V = $V$ + $upsilon$ , where (letting an overbar represent anaverage over trials) <A><AC>&ugr;</AC><AC>&cjs1171;</AC></A> = 0 and = $sigma$ ². One can then derive an equation for _T( $V$ ), the average response(averaged over the stochastic noise) as a function of the trial-averagedvoltage $V$ (see Fig. 2A; APPENDIX B). Experimental resultsusually report the stimulus-induced response with background responsesubtracted off. Thus we will study the quantity

<IT><A><AC>R</AC><AC>&cjs1171;</AC></A>T</IT>(<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT>)<IT>=</IT><IT><A><AC>r</AC><AC>&cjs1171;</AC></A>T</IT>(<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT>)<IT>−</IT><IT><A><AC>r</AC><AC>&cjs1171;</AC></A>T</IT>(<IT>0</IT>) (2)

We work in units of the noise, taking $sigma$ $triple-bond$ 1. In these units, both $V$ and T are measured as number of SDs of the noise aboverest e.g., T = 3 means that threshold is 3 noise SDs above rest.We take the gain k to be 1, which simply sets the units of response.With these choices, the form of the function _T( $V$ ) is determinedby the single parameter T.

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Fig. 2. A: how noise converts a linear threshold function (dashed line) into a smooth function (solid line). The response r is given by a linear threshold function of the voltage, r(V) = k[V $-$ T]⁺ (dotted line). Assuming V = $V$ + $upsilon$ , where $upsilon$ is 0-mean Gaussian noise (shown in gray), the average response vs. average voltage $V$ follows the smooth solid line. Diamond shows ( $V$ , ) for the Gaussian shown. Values illustrated were taken from those observed experimentally ( $sigma$ _noise = 3.5 mV, $V$ = 12 mV = 3.43 $sigma$ _noise, T = 10 mV = 2.86 $sigma$ _noise; see discussion in text section Comparison to experimental data). B: the smooth function that arises from the combination of noise and a linear-threshold response function closely approximates a power law. Mean output _T (vertical axes) is shown vs. mean voltage $V$ (horizontal axes), on linear axes (top) or as log-log plots (bottom) for varying values of threshold T. Continuous curves: exact noise-smoothed function _T (Eqs. 2 and B1). Dashed lines: best-fitting power law k $V$ ⁿ. Both $V$ and T are expressed as number of SDs of the noise above rest. Dotted vertical lines: $V$ = T + 1.5, the upper boundary of the region over which the power law was fit. Thin solid horizontal lines: _T = 0.1. Power law provides a good fit to _T wherever $V$ $<=$ T + 1.5 and _T $>=$ 0.1. x axes extend from 0 to T + 3 (top plots) or from 0.1 to 10 (bottom plots). Power law was found as fit giving least mean-square error over 0 $<=$ $V$ $<=$ T + 1.5, using Matlab 6.0 function fminsearch.

Figure 2B, top, shows _T versus $V$ as continuous lines for a range of values of threshold T. To determine how well this functionmight be approximated by a power law, for each T, we found thebest-fit power law k $V$ ⁿ (least-mean-squares fit;shown as dashed lines) over the range0 $<=$ $V$ $<=$ T + $V$ _hi (upper limit shown as vertical dotted line segments).We illustrate, and initially consider, the case $V$ _hi = 1.5. Thepower law gives an excellent fit to $V$ over the fitted range forall values of T. Fig. 2B, bottom, shows the same fits on a log-logplot. This shows that the power law fails for small inputs. However,these small inputs correspond to very low output rates (_T =0.1 shown as thin horizontal lines) that occur only for valuesof $V$ well below threshold and result in negligible absolute differencesbetween actual and fittedfunctions.

The best-fit exponent [n in the power law _T $approx$ k([ $V$ ]⁺)ⁿ] is always greater than one and increases with increasing thresholdT (Fig. 3). Intuitively, a larger exponent means that the response $V$ ⁿ remains small for larger values of $V$ , consistent with a higherthreshold (cf. Carandini et al. 1997). Note that because the thresholdT is expressed in units of the noise, increasing T for fixed noiseis equivalent to decreasing the noise for fixed T. Thus the exponentis expected to be a decreasing function of noise level, i.e.,higher noise leads to lower exponents (Anderson et al. 2000).

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Fig. 3. Dependence of power-law exponent n(T) on threshold T, for best-fit power law k(T) $V$ ^n(T). Fits were done as described in legend of Fig. 2.

We quantified the robustness of the power law approximation to _T( $V$ ) in two ways. First, for each value of thethreshold T, we calculated the size of the error at a given voltage $V$ relative to the size of the response _T( $V$ ), i.e., we plot|_T( $V$ ) $-$ k $V$ ⁿ |/_T( $V$ ) for a range of values of $V$ and T (Fig. 4). (Recallthat k and n are determined from optimizing the fit for 0 $<=$ $V$ $<=$ T + 1.5). Not surprisingly, the power law breaks down for large $V$ . In this range, all values of $V$ + $upsilon$ are above threshold, andthe input-output function becomes the underlying linear thresholdfunction. For low thresholds, the best fit power-law is more nearlylinear (exponents near 1.0, see Fig. 3) and a good fit extendswell beyond T + 1.5 (T + 1.5 is indicated by the upper dashedline in Fig. 4). For T > 2, however, accurate power-law fits donot extend much beyond this upper bound of the fitting range.The power law also breaks down for small values of $V$ . This indicatesthat the power-law fit does not capture the exact shape of thetransfer function as it bends away from _T = 0 (see Fig. 2B).However, errors at small $V$ correspond to very low firing rates(_T <0.1 shown as lower dashed line in Fig. 4). At such low rates,these large relative errors reflect small absolute differencesbetween _T( $V$ ) and the best-fit power law (see Fig. 2B, top).

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Fig. 4. Error of the best-fit power-law approximation k $V$ ⁿ, expressed relative to the trial-averaged response _T. Relative error is plotted versus threshold T (horizontal axis) and input $V$ (vertical axis). Relative error is defined as |_T( $V$ ) $-$ k $V$ ⁿ |/_T( $V$ ) (expressed as a percentage). This error is indicated as grayscale, linear from black = 0 to white = 50%; all values $>=$ 50% are set to white. Upper dashed line indicates $V$ = T + 1.5, the upper boundary of the region over which the power law was fit. Lower dashed line indicates contour along which = 0.1. As in Fig. 2, k(T) and n(T) in power law k $V$ ⁿ were fit separately for each T over the range 0 $<=$ $V$ $<=$ T + 1.5. Regions of large relative error below the = 0.1 contour show little absolute error: if absolute error |_T( $V$ ) $-$ k $V$ ⁿ | rather than relative error is plotted on the same scale (i.e., black = 0, white = 0.5), these regions become black (not shown; see also Fig. 2).

To determine the range of voltages over which the power-law can give a good fit, we varied V_hi, the upper voltage cutoff ofthe range of fit [0, T + V_hi]. For each V_hi, we calculated theaverage absolute error of the approximation (Fig. 5A), and theaverage error relative to the response (Fig. 5B), for integralvalues of threshold T from 1 to 5. As T increases beyond 2 SDsof the noise, good power-law fits are only obtained for rangesthat extend about 1.5 SDs above threshold.

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Fig. 5. Average absolute error (A) and average relative error (B) for variations of the upper bound V_hi of the range over which a power law was fit. Power law was fit over range 0 $<=$ $V$ $<=$ T + V_hi. Error is plotted vs. V_hi. Average absolute error is average over V $is in$ [0, T + V_hi] of |_T( $V$ ) $-$ k $V$ ⁿ |, while average relative error is average over the same range of |_T( $V$ ) $-$ k $V$ ⁿ |/_T( $V$ ). The five lines in each plot correspond to T = 1, 2, 3, 4, 5, as labeled. For T > 1, error rapidly grows for V_hi > 1.5; previous figures showed results for V_hi = 1.5.

In summary, both methods of assessing the accuracy of power law fits reveal that, across a wide range of thresholds, a powerlaw gives a good fit in the range [0, T + 1.5].

Comparison to experimental data

We can compare these results to data as follows. The noise in the recordings of Anderson et al. (2000) was generally $sigma$ = 3-4mV (rms). Their thresholds were roughly 10 mV from rest, yieldingT = 2.5-3.3 (expressed in units of the noise). Stimulus-inducedvoltage changes (DC + F1) at the highest contrast studied at thepreferred orientation were in the range of 8-12 mV, yielding $V$ = 2-4 (again in units of the noise) or no more than 1.5 aboveT. (Only contrasts $<=$ 64% were studied, but responses of most catV1 cells are nearly or entirely saturated at that contrast, e.g.,Albrecht 1995.) Thus they found that even the strongest visualcortical voltage responses remain in the range in which a linearthreshold function yields a power law as the averaged input-outputfunction.

A power law with exponent n is expected to sharpen tuning by a factor of $radical$ n. This is based on consideration of a Gaussiantuning curve: if such a curve has SD $sigma$ , raising it to the powern produces a curve with SD $sigma$ / $radical$ n. Thus we can compare independentestimates of the exponent n, one obtained from measures of sharpeningof tuning, and the other obtained by using the relationship ofnoise levels to exponents shown in Fig. 3. The range T = 2.5-3.3obtained from the recordings of Anderson et al. (2000) yieldsexponents n = 2.9-3.7 (Fig. 3), corresponding to a sharpeningof tuning by factors of $radical$ n = 1.7-1.9. Carandini and Ferster (2000)found that voltage orientation tuning had a half-width-half-height(HWHH) of 38 ± 15° (mean ± SD, averaged over cells), while spikingorientation tuning had a HWHH of about 23 ± 8° [see also Volgushevet al. (2000), who also found spike tuning to be sharper thantuning of intracellular potentials]; however, their spiking tuningestimate was almost certainly overly broad, because their methodsdid not allow resolution of spiking HWHHs <20°. These mean valuesrepresent a sharpening by a factor of 1.65, the square of whichsuggests an exponent n = 2.72, which is attained in our modelwhen T = 2.3. Given that this is almost certainly an underestimateof the true sharpening, this agrees well with the estimate n =2.9-3.7. Gardner et al. (1999) examined the same issue using extracellularrecording by comparing the tuning predicted from a cell's noise-mappedlinear receptive field to that observed in response to gratings;they found sharpening corresponding to power-law exponents thathad a geometric mean across cells of 3.15. Under the assumptionthat the linear receptive field approximates the transformationof stimuli into membrane voltage, this degree of sharpening agreeswell with the noise-basedestimate.

	DISCUSSION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION APPENDIX A APPENDIX B REFERENCES

Here we have shown two things. First, a power law is the only input-output function that converts contrast-invariant voltagetuning into contrast-invariant spiking tuning. Second, given alinear-threshold function relating instantaneous voltage to instantaneousfiring rate, addition of Gaussian noise to the voltage yieldsa relationship between trial-averaged voltage and trial-averagedfiring rate that is well approximated by an expansive power law.This approximation seems quite good provided that the trial-averagedvoltage does not exceed the threshold by more than about 1.5 SDsof the noise. We have gone on to compare these results to existingdata. The voltage responses reported by Anderson et al. (2000)remained within the range in which a power law gives a good approximation,even at high contrasts. The exponents predicted from their reportednoise and threshold levels predict a sharpening of spiking tuning,relative to voltage tuning, that agrees well with published dataon the degree of such sharpening (Carandini and Ferster 2000;Gardner et al. 1999).

Mechanisms yielding contrast-invariant tuning

Anderson et al. (2000) used numerical simulations to demonstrate that neural noise and a threshold-linear transfer functioncould transform contrast-invariant voltage responses into contrast-invariantspike responses. Our results, both theoretical (APPENDIX A)and computational (Figs. 2 and 4), indicate that the invarianceof spike tuning was due to the fact that a noise-smoothed threshold-linearfunction is well approximated by a power law. Thus the approachof Anderson et al. (2000) to contrast-invariant orientation tuning,based on noise-smoothed linear threshold models, resembles phenomenologicaldescriptions in which a linear filtering of the stimulus is followedby an expansive power law nonlinearity (Carandini et al. 1997;Heeger 1992; Heeger et al. 1996). It would be interesting to seeif similar mechanisms explain contrast-invariance of other responseproperties, such as spatial frequency tuning (Albrecht and Hamilton1982).

However, a noise-induced power-law nonlinearity only explains half the problem of contrast-invariant tuning of V1 simple cells,namely how voltage tuning that scales with contrast is convertedinto spiking tuning that scales with contrast. The mechanismsby which the input to simple cells from neurons in the lateralgeniculate nucleus (LGN) is converted into voltage tuning thatscales with contrast remain to be elucidated. The voltage responsesdo not result from a simple linear filtering of the input as postulatedby the phenomenological models. If the voltage resulted from alinear filtering of the drifting sinusoidal grating stimulus,then the mean voltage would be independent of orientation andcontrast because changes in these parameters do not change meanluminance. The experiments of Anderson et al. (2000) found, instead,that the mean voltage responses to drifting sinusoidal gratingstimuli were well-tuned for orientation and grew with contrast.From a more neural point of view, one might expect the voltageresponse of a simple cell to arise from a linear filtering ofthe firing rates of the LGN neurons that are presynaptic to thatcell. Because LGN firing rates have a rectification nonlinearity $---$ theirfiring rates can greatly increase but can decrease only to zero $---$ theirmean rate of firing increases with contrast. However, the outputof such a filter should again be untuned for orientation becausethe mean responses of LGN cells are largely untuned for orientation,and the mean voltage response under a linear filtering of theLGN would be obtained by a weighted sum of the mean responsesof each LGN input (Ferster and Miller 2000; Troyer et al. 1998).Thus the observed voltage responses do not arise from a linearfiltering either of the stimulus or of the LGN firingrates.

This raises the question as to how this mean LGN input, which is untuned for orientation and grows with contrast, is convertedinto a tuned mean voltage response. We have suggested that feedforwardinhibition (inhibition from interneurons driven by LGN input)can suppress the untuned mean input from the LGN and hence explainthe lack of contrast-dependent responses to stimuli oriented perpendicularto the preferred orientation (Ferster and Miller 2000; Milleret al. 2001; Troyer et al. 1998; see also McLaughlin et al. 2000;Wielaard et al. 2001, who propose a similar feedforward inhibitorymechanism but in the context of a somewhat different circuit).The increases in mean voltage for preferred stimuli may arisethrough the interaction between cellular or circuit nonlinearitiesand the large voltage modulations experienced at these orientations:both the reversal potential nonlinearity and intracortical excitationfrom other cells with a threshold nonlinearity will cause stimulithat yield larger voltage modulations to be accompanied by largervoltage mean responses. That is, the tuning of the voltage meanmay largely be inherited from the tuning of the voltage modulation.More generally, the results of Anderson et al. (2000) point awayfrom the nonlinearities involved in converting intracellular voltagesto spikes (e.g., the threshold nonlinearity) as being the keyissue related to contrast-invariant tuning, and toward an investigationof mechanisms that contribute to the tuning properties of theintracellularvoltage.

Comparison to previous theoretical work

It is widely known that noise can smooth and in certain respects linearize a threshold nonlinearity (e.g., Knight 1972; Spekreijse1969; Stemmler 1996), making otherwise subthreshold inputs become"visible." However, the present work is showing something farmore specific, namely that the specific smooth function that resultsclosely approximates a power law. Furthermore it is key that itis the voltage deviations from background that are raised to apower [i.e., _T( $V$ ) = k([ $V$ ]⁺)ⁿ]. Had the form of the output function instead been, say, k([ $V$ $-$ T]⁺)ⁿ for T >0, this would not yield contrast-invariant tuning $---$ moreand more of the input would be suprathreshold at higher contrasts.Because the exact equation for _T (Eqs. 2 and B1) depends on $V$ only through its dependence on $V$ $-$ T, it is surprising that thisis well approximated by k $V$ ⁿ over a significant range $---$ we know of no simple analytic reasonwhy this empirical finding should betrue.

We are aware of two other works that relate threshold-linear functions and power laws. First, Carandini et al. (1997) showedgraphically that a power law can roughly approximate a thresholdlinear function with higher thresholds corresponding to largerexponents. This suggests that for some response properties, modelsbased on linear threshold and power law nonlinearities may yieldsimilar predictions. However, contrast-invariant orientation tuningrequires that where responses are significantly larger than zero,the ratio of responses between various orientations must remainconstant at different levels of contrast. Even though absolutedifferences between a power law and an unsmoothed linear thresholdfunction might be moderate, the relative error between the functionsis very large near threshold, and as a result linear thresholdmodels do not yield contrast-invariant tuning (Anderson et al.2000). The key point we are making is not simply that a linearthreshold function resembles a power law but rather that noiseconverts a linear threshold function into a different functionthat approximates a power law sufficiently closely to achievecontrast-invariant tuning. Second, in a finding close in spiritto the present work, Suarez and Koch (1989) showed that, givena linear threshold model, adding noise to the input that is uniformlydistributed over some range (or, having a population of cellsreceiving identical input but with a uniform distribution of thresholds)acts like taking the integral of the linear threshold function,yielding a quadratic input-output function. However, the argumentis not robust. It only yields a power law of the form k([ $V$ ]⁺)ⁿ [rather than k([ $V$ $-$ T]⁺)ⁿ] when the upper bound of the noise (at rest) is equal to spikethreshold and can only yield power law exponents exactly equalto2.

Conclusions

Neural noise can convert an instantaneous linear-threshold input-output function into a power-law relationship between meaninput and mean output. Given reports suggesting that spontaneousvoltage fluctuations ("noise") in neocortex in vivo are largeand of comparable size to stimulus-induced voltage modulations(Arieli et al. 1996; Azouz and Gray 1999; Ho and Destexhe 2000;Paré et al. 1998; Tsodyks et al. 1999), it will be of great interestto determine if the response properties of cells in other regionsof the neocortex are best modeled by an expansive power law nonlinearity.In particular, it will be interesting to see if such a power lawmight be related more generally to tuning for stimulus form thatis invariant to changes in stimulusmagnitude.

	APPENDIX A

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION APPENDIX A APPENDIX B REFERENCES

Here we show that a rectified power law ( $V$ ) = k([ $V$ ]⁺)ⁿ is the only static input-output function that converts contrast-invariantinput tuning into contrast-invariant output tuning, assuming that( $V$ ) is nondecreasing (an increase in voltage cannot give adecrease in response) and nonnegative. The more general expressionwithout the latter assumptions is also a form of powerlaw.

We let c be contrast, $theta$ be the other parameters (such as orientation) that show contrast-invariant tuning, $V$ be the inputand ( $V$ ) be the output. Contrast-invariant input tuning impliesthat

<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT>(<IT>c</IT><IT>, &thgr;</IT>)<IT>=</IT><IT>f</IT>(<IT>c</IT>)<IT>g</IT>(<IT>&thgr;</IT>) (A1)

for some continuous functions f, g, and we assume contrast scaling is nonnegative: f(c) $>=$ 0. Contrast-invariant output tuningimplies that

<IT><A><AC>R</AC><AC>&cjs1171;</AC></A></IT>(<IT>f</IT>(<IT>c</IT>)<IT>g</IT>(<IT>&thgr;</IT>))<IT>=</IT><IT>F</IT>(<IT>f</IT>(<IT>c</IT>))<IT>G</IT>(<IT>g</IT>(<IT>&thgr;</IT>)) (A2)

for some continuous functions F, G, and again nonnegativity of contrast scaling implies F $>=$ 0. We assume that F(x) and G(x)are differentiable, at least for x $not equal$ 0.

Differentiating both sides of Eq. A2 with respect to f and g yields

<FR><NU>d<IT><A><AC>R</AC><AC>&cjs1171;</AC></A></IT>(<IT>fg</IT>)</NU><DE><IT>d</IT><IT>f</IT></DE></FR><IT>=</IT><IT>g<A><AC>R</AC><AC>&cjs1171;</AC></A></IT><IT>′</IT>(<IT>V</IT>)<IT>=</IT><IT>F</IT><IT>′</IT>(<IT>f</IT>)<IT>G</IT>(<IT>g</IT>)<IT>=</IT><FR><NU><IT>d</IT>(<IT>F</IT>(<IT>f</IT>)<IT>G</IT>(<IT>g</IT>))</NU><DE><IT>d</IT><IT>f</IT></DE></FR> (A3)

<FR><NU>d<IT><A><AC>R</AC><AC>&cjs1171;</AC></A></IT>(<IT>fg</IT>)</NU><DE><IT>d</IT><IT>g</IT></DE></FR><IT>=</IT><IT>f<A><AC>R</AC><AC>&cjs1171;</AC></A></IT><IT>′</IT>(<IT>V</IT>)<IT>=</IT><IT>F</IT>(<IT>f</IT>)<IT>G</IT><IT>′</IT>(<IT>g</IT>)<IT>=</IT><FR><NU><IT>d</IT>(<IT>F</IT>(<IT>f</IT>)<IT>G</IT>(<IT>g</IT>))</NU><DE><IT>d</IT><IT>g</IT></DE></FR> (A4)

We begin by assuming that f, F(f), g, and G(g) are all nonzero. Then

<IT><A><AC>R</AC><AC>&cjs1171;</AC></A></IT><IT>′</IT>(<IT>V</IT>)<IT>=</IT><FR><NU><IT>F</IT><IT>′</IT>(<IT>f</IT>)<IT>G</IT>(<IT>g</IT>)</NU><DE><IT>g</IT></DE></FR><IT>=</IT><FR><NU><IT>F</IT>(<IT>f</IT>)<IT>G</IT><IT>′</IT>(<IT>g</IT>)</NU><DE><IT>f</IT></DE></FR> (A5)

which yields

(A6)

Here, n is an arbitrary constant; because the quantity on the left is a function only of c, and that in the middle is a functiononly of $theta$ , the only way these two quantities can be equal to oneanother is if they are both equal to a constant (something thatdepends neither on c or $theta$ ), which we call n. Focusing on the functionG, we obtain

<FR><NU><IT>G</IT><IT>′</IT>(<IT>g</IT>)</NU><DE><IT>G</IT>(<IT>g</IT>)</DE></FR><IT>=</IT><FR><NU><IT>n</IT></NU><DE><IT>g</IT></DE></FR> (A7)

Integrating both sides with respect to g yields

<LIM><OP>∫</OP></LIM> d<IT>g </IT><FR><NU><IT>G</IT><IT>′</IT>(<IT>g</IT>)</NU><DE><IT>G</IT>(<IT>g</IT>)</DE></FR><IT>=</IT><LIM><OP>∫</OP></LIM><IT> d</IT><IT>g </IT><FR><NU><IT>n</IT></NU><DE><IT>g</IT></DE></FR> (A8)

ln <IT>G</IT>(<IT>g</IT>)<IT>=</IT><IT>n</IT><IT> ln </IT><IT>g</IT><IT>+</IT><IT>k</IT><IT>1</IT> (A9)

where k₁ is a constant of integration. Exponentiating yields

(A10)

where k₂ = . Identical reasoning shows that F(f) = k₃fⁿ for some constant k₃. Therefore

<IT><A><AC>R</AC><AC>&cjs1171;</AC></A></IT>(<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT>)<IT>=</IT><IT><A><AC>R</AC><AC>&cjs1171;</AC></A></IT>(<IT>fg</IT>)<IT>=</IT><IT>F</IT>(<IT>f</IT>)<IT>G</IT>(<IT>g</IT>)<IT>=</IT><IT>k</IT><IT>2</IT><IT>k</IT><IT>3</IT><IT>fngn</IT><IT>=</IT><IT>k<A><AC>V</AC><AC>&cjs1171;</AC></A>n</IT> (A11)

where k = k₂k₃.

We obtained these results on the assumption that f, F, g, and G were all nonzero. Combining these results with the continuityof G and F, however, we can conclude that 1) G(0) = 0 and F(0)= 0 and 2) F and G are either strictly zero or strictly nonzero(and equal to a power law) on each open half-infinite interval( $-$ $infinity$ , 0) and (0, $infinity$ ). Finally, since we have assumed that f is nonnegativeand ( $V$ ) is nondecreasing and nonnegative, G(g) = 0 for g <0. Thus, over the full range of $V$

<IT><A><AC>R</AC><AC>&cjs1171;</AC></A></IT>(<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT>)<IT>=</IT><IT>k</IT>([<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT>]<IT>+</IT>)<IT>n</IT> (A12)

	APPENDIX B

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION APPENDIX A APPENDIX B REFERENCES

Let the voltage V = $V$ + $upsilon$ where overbar represents an average, <A><AC>&ugr;</AC><AC>&cjs1171;</AC></A> = 0 and = $sigma$ ². We assume the instantaneous spike rate is given by r_T(V) = k[V $-$ T]⁺. Then the trial-averaged spike rate is

<IT><A><AC>R</AC><AC>&cjs1171;</AC></A>T</IT>(<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT>)<IT>=</IT><IT>k</IT><OVL>[<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT><IT>+&ugr;−</IT><IT>T</IT>]<IT>+</IT></OVL>

=<FR><NU><IT>k</IT></NU><DE><RAD><RCD><IT>2&pgr;&sfgr;2</IT></RCD></RAD></DE></FR> <LIM><OP>∫</OP><LL><IT>T</IT><IT>−</IT><OVL><IT>V</IT></OVL></LL><UL><IT>∞</IT></UL></LIM><IT> d&ugr; exp</IT><FENCE>−<FR><NU><IT>&ugr;2</IT></NU><DE><IT>2&sfgr;2</IT></DE></FR></FENCE> (<IT><A><AC>V</AC><AC>&cjs1171;</AC></A></IT><IT>−</IT><IT>T</IT><IT>+&ugr;</IT>)

(B1)

where erf is the error function, erf (x) = (2/ $radical$ $pi$ ) $int$ dy exp( $-$ y²). To work in units of the noise, we set $sigma$ = 1 in Eq. B1.

	ACKNOWLEDGMENTS

We thank B. Bialek, J. Anderson, and D. Ferster for usefulconversations.

We gratefully acknowledge support by National Eye Institute Grant EY-11001 (K. D.Miller).

After this work was completed, we became aware that the independent work of D. Hansel and C. van Vreeswijk reached similarconclusions.

	FOOTNOTES

Address for reprint requests: K. D. Miller, Dept. of Physiology, UCSF, San Francisco, CA 94143-0444 (E-mail: ken{at}phy.ucsf.edu).

¹ We use the rectified voltage [V]⁺ in our definition of a power law to ensure that responses are an increasing function of voltage,i.e., we assume that hyperpolarization cannot increaseresponse.

Received 22 May 2001; accepted in final form 19 October 2001.

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