The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\pi^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^+$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^-$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential proton production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $K^0_S$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The double differential $\Lambda$ production cross section in the laboratory system for p+C interactions at 31 GeV$/c$. The results are presented as a function of momentum, $p$ (in [GeV/$c$]), in different angular intervals, $\theta$ (in [mrad]). The statistical and systematic errors are quoted.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.16-1.17, 1.17-1.18 and 1.18-1.19.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.19-1.20, 1.20-1.21 and 1.21-1.22.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.22-1.23, 1.23-1.24 and 1.24-1.25.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.25-1.26, 1.26-1.27 and 1.27-1.28.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.28-1.29, 1.29-1.30 and 1.30-1.31.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.31-1.32, 1.32-1.33 and 1.33-1.34.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.34-1.35, 1.35-1.36 and 1.36-1.37.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.37-1.38, 1.38-1.39 and 1.39-1.40.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.40-1.41, 1.41-1.42 and 1.42-1.43.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.43-1.44, 1.44-1.45 and 1.45-1.46.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.46-1.47, 1.47-1.48 and 1.48-1.49.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.49-1.50, 1.50-1.51 and 1.51-1.52.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.52-1.53, 1.53-1.54 and 1.54-1.55.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.55-1.56, 1.56-1.57 and 1.57-1.58.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.58-1.59, 1.59-1.60 and 1.60-1.61.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.61-1.62, 1.62-1.63 and 1.63-1.64.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.64-1.65, 1.65-1.66 and 1.66-1.67.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.67-1.68, 1.68-1.69 and 1.69-1.70.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.70-1.71, 1.71-1.72 and 1.72-1.73.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.73-1.74, 1.74-1.75 and 1.75-1.76.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.76-1.77, 1.77-1.78 and 1.78-1.79.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.79-1.80, 1.80-1.81 and 1.81-1.82.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.82-1.83, 1.83-1.84 and 1.84-1.85.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.85-1.86, 1.86-1.87 and 1.87-1.88.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.88-1.89, 1.89-1.90 and 1.90-1.92.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.92-1.94, 1.94-1.96 and 1.96-1.98.

The cos(Theta*) dependence of the differential cross section for the W ranges 1.98-2.00, 2.00-2.02 and 2.02-2.04.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.04-2.06, 2.06-2.08 and 2.08-2.10.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.10-2.12, 2.12-2.14 and 2.14-2.16.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.16-2.18, 2.18-2.20 and 2.20-2.22.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.22-2.24, 2.24-2.26 and 2.26-2.28.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.28-2.30, 2.30-2.32 and 2.32-2.34.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.34-2.36, 2.36-2.38 and 2.38-2.40.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.40-2.44, 2.44-2.48 and 2.48-2.52.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.52-2.56, 2.56-2.60 and 2.60-2.70.

The cos(Theta*) dependence of the differential cross section for the W ranges 2.70-2.80, 2.80-2.90 and 2.90-3.00.

The cos(Theta*) dependence of the differential cross section for the W ranges 3.00-3.10, 3.10-3.20 and 3.20-3.30.

Angular dependence of the differential cross section for the W range 1.160 to 1.200 GeV.

Angular dependence of the differential cross section for the W range 1.200 to 1.240 GeV.

Angular dependence of the differential cross section for the W range 1.240 to 1.280 GeV.

Angular dependence of the differential cross section for the W range 1.280 to 1.320 GeV.

Angular dependence of the differential cross section for the W range 1.320 to 1.360 GeV.

Angular dependence of the differential cross section for the W range 1.360 to 1.400 GeV.

Angular dependence of the differential cross section for the W range 1.400 to 1.440 GeV.

Angular dependence of the differential cross section for the W range 1.440 to 1.480 GeV.

Angular dependence of the differential cross section for the W range 1.480 to 1.520 GeV.

Angular dependence of the differential cross section for the W range 1.520 to 1.560 GeV.

Angular dependence of the differential cross section for the W range 1.560 to 1.600 GeV.

Angular dependence of the differential cross section for the W range 1.600 to 1.640 GeV.

Angular dependence of the differential cross section for the W range 1.640 to 1.680 GeV.

Angular dependence of the differential cross section for the W range 1.680 to 1.720 GeV.

Angular dependence of the differential cross section for the W range 1.720 to 1.760 GeV.

Angular dependence of the differential cross section for the W range 1.760 to 1.800 GeV.

Angular dependence of the differential cross section for the W range 1.800 to 1.840 GeV.

Angular dependence of the differential cross section for the W range 1.840 to 1.880 GeV.

Angular dependence of the differential cross section for the W range 1.880 to 1.920 GeV.

Angular dependence of the differential cross section for the W range 1.920 to 1.960 GeV.

Angular dependence of the differential cross section for the W range 1.960 to 2.000 GeV.

Angular dependence of the differential cross section for the W range 2.000 to 2.040 GeV.

Angular dependence of the differential cross section for the W range 2.040 to 2.080 GeV.

Angular dependence of the differential cross section for the W range 2.080 to 2.120 GeV.

Angular dependence of the differential cross section for the W range 2.120 to 2.160 GeV.

Angular dependence of the differential cross section for the W range 2.160 to 2.200 GeV.

Angular dependence of the differential cross section for the W range 2.200 to 2.240 GeV.

Angular dependence of the differential cross section for the W range 2.240 to 2.280 GeV.

Angular dependence of the differential cross section for the W range 2.280 to 2.320 GeV.

Angular dependence of the differential cross section for the W range 2.320 to 2.360 GeV.

Angular dependence of the differential cross section for the W range 2.360 to 2.400 GeV.

Angular dependence of the differential cross section for the W range 2.400 to 2.500 GeV.

Angular dependence of the differential cross section for the W range 2.500 to 2.600 GeV.

Angular dependence of the differential cross section for the W range 2.600 to 2.700 GeV.

Angular dependence of the differential cross section for the W range 2.700 to 2.800 GeV.

Angular dependence of the differential cross section for the W range 2.800 to 2.900 GeV.

Angular dependence of the differential cross section for the W range 2.900 to 3.000 GeV.

Angular dependence of the differential cross section for the W range 3.000 to 3.100 GeV.

Angular dependence of the differential cross section for the W range 3.100 to 3.200 GeV.

Angular dependence of the differential cross section for the W range 3.200 to 3.300 GeV.

Single differential cross section DSIG/DCOS(THETA).

Double differential cross section D2SIG/DM/DPT in the diphoton mass range 30 TO 50 GeV.

Double differential cross section D2SIG/DM/DPHI in the diphoton mass range 30 TO 50 GeV.

Double differential cross section D2SIG/DM/DCOS(THETA) in the diphoton mass range 30 TO 50 GeV.

Double differential cross section D2SIG/DM/DPT in the diphoton mass range 50 TO 80 GeV.

Double differential cross section D2SIG/DM/DPHI in the diphoton mass range 50 TO 80 GeV.

Double differential cross section D2SIG/DM/DCOS(THETA) in the diphoton mass range 50 TO 80 GeV.

Double differential cross section D2SIG/DM/DPT in the diphoton mass range 80 TO 350 GeV.

Double differential cross section D2SIG/DM/DPHI in the diphoton mass range 80 TO 350 GeV.

Double differential cross section D2SIG/DM/DCOS(THETA) in the diphoton mass range 80 TO 350 GeV.

Differential cross section for W = 0.79, 0.81 and 0.83 GeV.

Differential cross section for W = 0.85, 0.87 and 0.89 GeV.

Differential cross section for W = 0.91, 0.93 and 0.95 GeV.

Differential cross section for W = 0.97, 0.99 and 1.01 GeV.

Differential cross section for W = 1.03, 1.05 and 1.07 GeV.

Differential cross section for W = 1.09, 1.11 and 1.13 GeV.

Differential cross section for W = 1.15, 1.17 and 1.19 GeV.

Differential cross section for W = 1.21, 1.23 and 1.25 GeV.

Differential cross section for W = 1.27, 1.29 and 1.31 GeV.

Differential cross section for W = 1.33, 1.35 and 1.37 GeV.

Differential cross section for W = 1.39, 1.41 and 1.43 GeV.

Differential cross section for W = 1.45, 1.47 and 1.49 GeV.

Differential cross section for W = 1.51, 1.53 and 1.55 GeV.

Differential cross section for W = 1.57, 1.59 and 1.61 GeV.

Differential cross section for W = 1.63, 1.65 and 1.67 GeV.

Differential cross section for W = 1.69, 1.71 and 1.73 GeV.

Differential cross section for W = 1.75, 1.77 and 1.79 GeV.

Differential cross section for W = 1.82, 1.86 and 1.90 GeV.

Differential cross section for W = 1.94, 1.98 and 2.02 GeV.

Differential cross section for W = 2.06, 2.10 and 2.14 GeV.

Differential cross section for W = 2.18, 2.22 and 2.26 GeV.

Differential cross section for W = 2.30, 2.34 and 2.38 GeV.

Differential cross section for W = 2.45, 2.55 and 2.65 GeV.

Differential cross section for W = 2.75, 2.85 and 2.95 GeV.

Differential cross section for W = 3.05, 3.15 and 3.65 GeV.

Differential cross section for W = 3.75, 3.85 and 3.95 GeV.

Differential cross section for W = 4.05 GeV.

Total cross section for the two cos(theta*) ranges, < 0.6 and < 0.8.

Differential cross section for W = 0.79, 0.81 and 0.83 GeV.

Differential cross section for W = 0.85, 0.87 and 0.89 GeV.

Differential cross section for W = 0.91, 0.93 and 0.95 GeV.

Differential cross section for W = 0.97, 0.99 and 1.01 GeV.

Differential cross section for W = 1.03, 1.05 and 1.07 GeV.

Differential cross section for W = 1.09, 1.11 and 1.13 GeV.

Differential cross section for W = 1.15, 1.17 and 1.19 GeV.

Differential cross section for W = 1.21, 1.23 and 1.25 GeV.

Differential cross section for W = 1.27, 1.29 and 1.31 GeV.

Differential cross section for W = 1.33, 1.35 and 1.37 GeV.

Differential cross section for W = 1.39, 1.41 and 1.43 GeV.

Differential cross section for W = 1.45, 1.47 and 1.49 GeV.

Differential cross section for W = 1.51, 1.53 and 1.55 GeV.

Differential cross section for W = 1.57, 1.59 and 1.62 GeV.

Differential cross section for W = 1.66, 1.70 and 1.74 GeV.

Differential cross section for W = 1.78, 1.82 and 1.86 GeV.

Differential cross section for W = 1.90, 1.94 and 1.98 GeV.

Differential cross section for W = 2.02, 2.06 and 2.10 GeV.

Differential cross section for W = 2.14, 2.18 and 2.22 GeV.

Differential cross section for W = 2.26, 2.30 and 2.34 GeV.

Differential cross section for W = 2.38, 2.45 and 2.55 GeV.

Differential cross section for W = 2.65, 2.75 and 2.85 GeV.

Differential cross section for W = 2.95, 3.05 and 3.15 GeV.

Differential cross section for W = 3.25, 3.65 and 3.75 GeV.

Differential cross section for W = 3.85 and 3.95 GeV.

Total cross section for the cos(theta*) ranges 0.0 to 0.6 and 0.0 to 0.8.

COS(THETA*) distribution for leptonic W decay in lepton+jets events.. The data in this table are PRELIMINARY and taken from D0 Note 5722-CONF. Data are read from plots and errors are statistcial (sqrt(N)).

COS(THETA*) distribution for hadronic W decay in lepton+jets events.. The data in this table are PRELIMINARY and taken from D0 Note 5722-CONF. Data are read from plots and errors are statistcial (sqrt(N)).

COS(THETA*) distribution for W decay in dilepton events.. The data in this table are PRELIMINARY and taken from D0 Note 5722-CONF. Data are read from plots and errors are statistcial (sqrt(N)).

Measured cross section for combined fit to all data.

Measured differential cross section as a function of the W- production angle.

Angular distribution of the cross section in the W range 2.6 to 2.8 GeV.

Angular distribution of the cross section in the W range 2.8 to 3.3 GeV.

Angular distribution of the cross section in the ABS(W-M(CHI(C0))) range < 66 MeV.

Angular distribution of the cross section in the ABS(W-M(CHI(C2))) range < 36 MeV.

Measured MU+ MU- cross section for the high-energy data sample.

Measured TAU+ TAU- cross section for the inclusive data sample.

Measured TAU+ TAU- cross section for the high-energy data sample.

Measured E+ E- --> E+ E- cross section for the inclusive data sample.

Measured E+ E- --> E+ E- cross section for the high-energy data sample.

Measured Forward-Backward asymmetry in MU+ MU- production from the inclusive data sample.

Measured Forward-Backward asymmetry in MU+ MU- production from the high-energy data sample.

Measured Forward-Backward asymmetry in TAU+ TAU- production from the inclusive data sample.

Measured Forward-Backward asymmetry in TAU+ TAU- production from the high-energy data sample.

Measured Forward-Backward asymmetry in E+ E- production for the inclusive data sample.

Measured Forward-Backward asymmetry in E+ E- production for the high-energy data sample.

Differential cross sections for E+ E- production as a function of the scattering angle for the high-energy data sample for centre of mass energy 192 GeV.

Differential cross sections for E+ E- production as a function of the scattering angle for the high-energy data sample for centre of mass energy 196 GeV.

Differential cross sections for E+ E- production as a function of the scattering angle for the high-energy data sample for centre of mass energy 200 GeV.

Differential cross sections for E+ E- production as a function of the scattering angle for the high-energy data sample for centre of mass energy 202 GeV.

Differential cross sections for E+ E- production as a function of the scattering angle for the high-energy data sample for centre of mass energy 205 GeV.

Differential cross sections for E+ E- production as a function of the scattering angle for the high-energy data sample for centre of mass energy 207 GeV.

Differential cross sections for E+ E- production as a function of the scattering angle for the high-energy data sample for centre of mass energy 208 GeV.