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HERA combined reduced cross sections $\sigma_{r,\rm NC}^{+}$ for NC $e^{+}p$ scattering at $\sqrt{s} = 225$ GeV; $\delta_{\rm stat}$, $\delta_{\rm uncor}$ and $\delta_{\rm cor}$ represent the statistical, uncorrelated systematic and correlated systematic uncertainties, respectively; $\delta_{\rm rel}$, $\delta_{\gamma p}$, $\delta_{\rm had}$ and $\delta_{1}$ to $\delta_{4}$ are the correlated sources of uncertainties arising from the combination procedure. The uncertainties are quoted in percent relative to $\sigma_{r,\rm NC}^{+}$.

HERA combined reduced cross sections $\sigma_{r,\rm NC}^{-}$ for NC $e^{-}p$ scattering at $\sqrt{s} = 318$ GeV; $\delta_{\rm stat}$, $\delta_{\rm uncor}$ and $\delta_{\rm cor}$ represent the statistical, uncorrelated systematic and correlated systematic uncertainties, respectively; $\delta_{\rm rel}$, $\delta_{\gamma p}$, $\delta_{\rm had}$ and $\delta_{1}$ to $\delta_{4}$ are the correlated sources of uncertainties arising from the combination procedure. The uncertainties are quoted in percent relative to $\sigma_{r,\rm NC}^{-}$.

HERA combined reduced cross sections $\sigma_{r,\rm CC}^{+}$ for CC $e^{+}p$ scattering at $\sqrt{s} = 318$ GeV; $\delta_{\rm stat}$, $\delta_{\rm uncor}$ and $\delta_{\rm cor}$ represent the statistical, uncorrelated systematic and correlated systematic uncertainties, respectively; $\delta_{\rm rel}$, $\delta_{\gamma p}$, $\delta_{\rm had}$ and $\delta_{1}$ to $\delta_{4}$ are the correlated sources of uncertainties arising from the combination procedure. The uncertainties are quoted in percent relative to $\sigma_{r,\rm CC}^{+}$.

HERA combined reduced cross sections $\sigma_{r,\rm CC}^{-}$ for CC $e^{-}p$ scattering at $\sqrt{s} = 318$ GeV; $\delta_{\rm stat}$, $\delta_{\rm uncor}$ and $\delta_{\rm cor}$ represent the statistical, uncorrelated systematic and correlated systematic uncertainties, respectively; $\delta_{\rm rel}$, $\delta_{\gamma p}$, $\delta_{\rm had}$ and $\delta_{1}$ to $\delta_{4}$ are the correlated sources of uncertainties arising from the combination procedure. The uncertainties are quoted in percent relative to $\sigma_{r,\rm CC}^{-}$.

Structure function $xF_3^{\gamma Z}$ for different values of $Q^2$ and $x_{\rm Bj}$.

Structure function $xF_3^{\gamma Z}$ averaged over $Q^2 \ge 1000$ GeV$^2$ at the scale 1000 GeV$^2$.

The measured F2 and xF3 at X = 0.125.

The measured F2 and xF3 at X = 0.175.

The measured F2 and xF3 at X = 0.225.

The measured F2 and xF3 at X = 0.275.

The measured F2 and xF3 at X = 0.350.

The measured F2 and xF3 at X = 0.450.

The measured F2 and xF3 at X = 0.550.

The measured F2 and xF3 at X = 0.650.

The measured R (=sigL/sigT)) at X = 0.020.

The measured R (=sigL/sigT)) at X = 0.045.

The measured R (=sigL/sigT)) at X = 0.080.

The measured R (=sigL/sigT)) at X = 0.125.

The measured R (=sigL/sigT)) at X = 0.175.

The measured R (=sigL/sigT)) at X = 0.225.

The measured R (=sigL/sigT)) at X = 0.275.

The measured R (=sigL/sigT)) at X = 0.350.

The measured R (=sigL/sigT)) at X = 0.450.

The measured R (=sigL/sigT)) at X = 0.550.

The measured R (=sigL/sigT)) at X = 0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 25.0 GeV and X =0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 35.0 GeV and X =0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 45.0 GeV and X =0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 55.0 GeV and X =0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 70.0 GeV and X =0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 90.0 GeV and X =0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 110.0 GeV and X =0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 130.0 GeV and X =0.650.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.020.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.045.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.080.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.125.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.175.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.225.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.275.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.350.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.450.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.550.

Measured cross sections for neutrino and anti-neutrino interactions at a mean energy 170.0 GeV and X =0.650.

Measurement of F2 at X = 0.125.

Measurement of F2 at X = 0.175.

Measurement of F2 at X = 0.225.

Measurement of F2 at X = 0.275.

Measurement of F2 at X = 0.350.

Measurement of F2 at X = 0.450.

Measurement of F2 at X = 0.550.

Measurement of F2 at X = 0.650.

Measurement of F2 at X = 0.750.

Measurement of XF3 at X = 0.015.

Measurement of XF3 at X = 0.045.

Measurement of XF3 at X = 0.080.

Measurement of XF3 at X = 0.125.

Measurement of XF3 at X = 0.175.

Measurement of XF3 at X = 0.225.

Measurement of XF3 at X = 0.275.

Measurement of XF3 at X = 0.350.

Measurement of XF3 at X = 0.450.

Measurement of XF3 at X = 0.550.

Measurement of XF3 at X = 0.650.

Measurement of XF3 at X = 0.750.

Differential cross sections at neutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

The NC cross section DSIG/DX for Q**2 > 10000 GeV**2. There is an additional 1.5 PCT normalization uncertainty.

The CC cross section DSIG/DX for Q**2 > 1000 GeV**2. There is an additional 1.5 PCT normalization uncertainty.

The NC reduced cross section and the electromagnetic structure funcion F2 derived from the data. For Q**2 > 2000 GeV**2 the extraction of F2 is restricted to Y < 0.6.

The CC double differential cross section D2SIG/DX/DQ**2 and the structure function term PHI.

The NC E- P reduced cross section for the high-y analysis. All E- P data not previously reported in EPJ C19 (2001) 269 are given.. There is an additional 1.8 PCT normalization uncertainty.

The NC structure function term PHI and the structure function FL for the E-P data.

The NC structure function term PHI and the structure function FL for the E+P data.

The generalised structure function XF3.

The structure function XF3(C=GAMMA,Z) obtained by averaging over different Q**2 values and transforming to Q**2 = 1500 GeV**2.

Breakdown of errors from table 6, DSIG(C=NC)/DQ**2 as a function of Q**2. All errors are in PCT.

All errors are in PCT.

Breakdown of errors from table 8, DSIG(C=NC)/DX as a function of X. All errors are in PCT.

Breakdown of errors from table 9, DSIG(C=NC)/DX as a function of X. All errors are in PCT.

Breakdown of errors from table 10, DSIG(C=CC)/DX as a function of X. All errors are in PCT.

Breakdown of errors from table 11, F2 as a function of Q**2, X and Y. All errors are in PCT.

Breakdown of errors from table 11, F2 as a function of Q**2, X and Y. PHI(C=NC) is the NC structure function term.. Y+ = 1+(1-Y)**2. DEL(F2),DEL9F3) and DEL(FL) are the corrections to F2 as decribed in the text of the paper.

All errors are in PCT.

Breakdown of errors from table 12, SIG(C=REDUCED) as a function of Q**2 andX. All errors are in PCT.

The reduced cross section in the Q**2 regions 185 to 240 and 240 to 310 GeV**2.

The reduced cross section in the Q**2 regions 310 to 410 and 410 to 530 GeV**2.

The reduced cross section in the Q**2 regions 530 to 710 and 710 to 900 GeV**2.

The reduced cross section in the Q**2 regions 900 to 1300 and 1300 to 1800 GeV**2.

The reduced cross section in the Q**2 regions 1800 to 2500 and 2500 to 3500GeV**2.

The reduced cross section in the Q**2 regions 3500 to 5600 and 5600 to 9000GeV**2.

The reduced cross section in the Q**2 regions 9000 to 15000 ,15000 to 25000and 125000 to 50000 GeV**2.

The structure function XF3 determined tegether with the ZEUS E+ P data at the mean Q**2 values of 1500 and 3000 GeV**2.

The structure function XF3 determined tegether with the ZEUS E+ P data at the mean Q**2 values of 5000 and 8000 GeV**2.

The structure function XF3 determined tegether with the ZEUS E+ P data at the mean Q**2 values of 12000 and 30000 GeV**2.

Details of the systematic uncertainties for the cross section DSIG/DQ**2 measurement.

Details of the systematic uncertainties for the cross section DSIG/DX measurement.

Details of the systematic uncertainties for the cross section DSIG/DX measurement.

Details of the systematic uncertainties for the cross section DSIG/DY measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

Details of the systematic uncertainties in the reduced cross section measurement.

The NC single differential cross section, as a function of Q**2 in the range from 200 to 30000 Gev**2, for Y < 0.9 after correction (KCOR) according to theStandard Model expectation from the measured kinematic cuts y < 0.63 for Q**2 < 890 GeV**2. The first DSYS error is the uncorrelated systematic error and the second is the correlated systematic error.

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The structure function, F2, and the reduced cross section, in NC DIS scattering at Q**2 from 150 to 30000 GeV**2 as a function if x and y. The individual corrections used to calculate F2 from the cross sections are given in the following table.

The various corrections to the cross sections used to calcuate the F2 values given in the previous table. See the text of the paper for more details.

The CC double differential cross section and the structure function term PHI(C=CC) - see text of the paper for details - at Q**2 from 150 to 1 5000 GeV**2 as a function of both x and y. Also tabulated are the QED corrections to the data, which have already been applied.

CT = The various sources of error (in percent) to the individual NC reduced cross section given in table 6 - see text of paper for more details;DTOT - TOTAL error. DSTA - STATISTICAL error. DUNC - UNCORRELATED SYSTEMATIC error. DUNC(E) - UNCORRELATED SYSTEMATIC error from the positron energy. DUNC(H) - UNCORRELATED SYSTEMATIC error from the hadronic energy. DCOR - CORRELATED SYSTEMATIC error. DCOR(E+) - CORRELATED SYSTEMATIC from one sig variation in the positron energy. DCOR(T+) - CORRELATED SYSTEMATIC from one sig variation in the positron polar angle. DCOR(H+) - CORRELATED SYSTEMATIC from one sig variation in the hadron energy. DCOR(N+) - CORRELATED SYSTEMATIC from one sig variation in the noise subtraction. DCOR(B+) - CORRELATED SYSTEMATIC from one sig variation in the background subtraction.

The various sources of error (in percent) to the individual CC double differential cross sections given in table 7 - see text of paper for more details. DTOT - TOTAL error. DSTA - STATISTICAL error. DUNC - UNCORRELATED SYSTEMATIC error. DUNC(H) - UNCORRELATED SYSTEMATIC error from the hadronic energy. DCOR - CORRELATED SYSTEMATIC error. DCOR(V+) - CORRELATED SYSTEMATIC from one sig variationin the cut on the Vap/Vp ratio. DCOR(H+) - CORRELATED SYSTEMATIC from one sig variation in the hadron energy. DCOR(N+) - CORRELATED SYSTEMATIC from one sig variation in the noise subtraction. DCOR(B+) - CORRELATED SYSTEMATIC from one sig variation in the background subtraction.

The structure function xF3 dtermined by combining the present NC E- data with previously measured E+ data at a proton enetrgy of 820 GeV. (Adloff et al. EPJ C13 (609) 2000.). The luminosity uncertainties of the E+ P and E- P data sets are included in the systematic error.

The total CC cross section in the region Q**2 > 1000 GeV**2 and Y > 0.9 after applying a small correction factor from the measured Y range from 0.03 0.85.

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Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Structure functions for neutrino and antineutrino combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

Neutrino and Antineutrino data combined.

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STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 6 PCT. FOR F2 , 8 PCT. FOR XF3.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.

STUCTURE FUNCTIONS ARE EVALUATED ASSUMING R=SIG(L)/SIG(T)=0.1 AND M(W) IS INFINITE. NO CORRECTION FOR FERMI MOTION APPLIED. ERRORS ARE STATISTICAL AND SYSTEMATIC POINT-TO-POINT ERRORS. IN ADDITION OVER-ALL SCALE ERROR OF 8 PCT. FOR ANTI-QUARK STRUCTURE FUNCTION.