Target asymmetry for $p\pi^0$ as a function of the polar angle for bins of the incident photon energy in the range of $E_\gamma$ = 650-2600 MeV.

Target asymmetry for $p\pi^0$ as a function of the $p\pi0$ invariant mass for bins of the incident photon energy in the range of $E_\gamma$ = 650-2600 MeV.

Target asymmetry for $p\pi^0$ as a function of the $\phi^*$ angle for bins of the incident photon energy in the range of $E_\gamma$ = 650-2600 MeV.

Double polarization observables for $\pi^0\pi^0$ as a function of the polar angle for bins of the incident photon energy in the range of $E_\gamma$ = 650-950 MeV.

Double polarization observables for $\pi^0\pi^0$ as a function of the $\pi^0\pi0$ invariant mass for bins of the incident photon energy in the range of $E_\gamma$ = 650-950 MeV.

Double polarization observables for $\pi^0\pi^0$ as a function of the polar angle for bins of the incident photon energy in the range of $E_\gamma$ = 650-950 MeV.

Double polarization observables for $p\pi^0$ as a function of the $p\pi0$ invariant mass for bins of the incident photon energy in the range of $E_\gamma$ = 650-950 MeV.

Double polarization observables for $\pi^0\pi^0$ as a function of the $\phi^*$ angle for bins of the incident photon energy in the range of $E_\gamma$ = 650-950 MeV.

Double polarization observables for $p\pi^0$ as a function of the $\phi^*$ angle for bins of the incident photon energy in the range of $E_\gamma$ = 650-950 MeV.

Target asymmetries for $\pi^0\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 650-800 MeV.

Target asymmetries for $\pi^0\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 800-950 MeV.

Target asymmetries for $\pi^0\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 950-1100 MeV.

Target asymmetries for $\pi^0\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 1100-1250 MeV.

Target asymmetries for $p\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 650-800 MeV.

Target asymmetries for $p\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 800-950 MeV.

Target asymmetries for $p\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 950-1100 MeV.

Target asymmetries for $p\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 1100-1250 MeV.

Double polarization observables for $\pi^0\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 650-800 MeV.

Double polarization observables for $\pi^0\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 800-950 MeV.

Double polarization observables for $p\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 650-800 MeV.

Double polarization observables for $p\pi^0$ as a function of $\cos\vartheta$, invariant mass and $\phi^*$ for bins of the incident photon energy in the range of $E_\gamma$ = 800-950 MeV.

Measured beam asymmetry I_S as a function of the angle between the reaction plane and the plane of the two final state particles with the the pi0 as the recoiling particle for the cm energy range 1642 to 1770 MeV.

Measured beam asymmetry I_S as a function of the angle between the reaction plane and the plane of the two final state particles with the the pi0 as the recoiling particle for the cm energy range 1770 to 1898 MeV.

Measured beam asymmetry I_S as a function of the angle between the reaction plane and the plane of the two final state particles with the the pi0 as the recoiling particle for the cm energy range 1898 to 1994 MeV.

Measured beam asymmetry I_S as a function of the angle between the reaction plane and the plane of the two final state particles with the the eta as the recoiling particle for the cm energy range 1642 to 1770 MeV.

Measured beam asymmetry I_S as a function of the angle between the reaction plane and the plane of the two final state particles with the the eta as the recoiling particle for the cm energy range 1770 to 1898 MeV.

Measured beam asymmetry I_S as a function of the angle between the reaction plane and the plane of the two final state particles with the the eta as the recoiling particle for the cm energy range 1898 to 1994 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the proton as the recoiling particle for the cm energy range 1642 to 1770 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the proton as the recoiling particle for the cm energy range 1770 to 1898 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the proton as the recoiling particle for the cm energy range 1898 to 1994 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the pi0 as the recoiling particle for the cm energy range 1642 to 1770 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the pi0 as the recoiling particle for the cm energy range 1770 to 1898 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the pi0 as the recoiling particle for the cm energy range 1898 to 1994 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the eta as the recoiling particle for the cm energy range 1642 to 1770 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the eta as the recoiling particle for the cm energy range 1770 to 1898 MeV.

Measured beam asymmetry I_C as a function of the angle between the reaction plane and the plane of the two final state particles with the the eta as the recoiling particle for the cm energy range 1898 to 1994 MeV.

Measured values of the LAMBDA polarization as a function of PT in the XL range 0.4 to 0.5.

Measured values of the LAMBDA polarization as a function of PT in the XL range 0.5 to 0.6.

Measured values of the LAMBDA polarization as a function of PT in the XL range 0.6 to 0.7.

Measured values of the LAMBDA polarization as a function of PT in the XL range 0.7 to 0.8.

Measured values of the LAMBDA polarization as a function of PT in the XL range 0.8 to 0.9.

Measured values of CNN at EKIN 2035 Mev (from run period IV).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.056.

Measured values of CNN at EKIN 2115 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.046.

Measured values of CNN at EKIN 2155 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.039.

Measured values of CNN at EKIN 2175 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.041.

Measured values of CNN at EKIN 2215 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.038.

Measured values of CNN at EKIN 2225 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.049.

Measured values of CNN at EKIN 2235 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.043.

Measured values of CNN at EKIN 2245 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.048.

Measured values of CNN at EKIN 2395 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.047.

Measured values of CNN at EKIN 2445 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.049.

Measured values of CNN at EKIN 2495 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.043.

Measured values of CNN at EKIN 2515 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.044.

Measured values of CNN at EKIN 2565 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.044.

Measured values of CNN at EKIN 2575 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.044.

Measured values of CNN at EKIN 2595 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.042.

Measured values of CNN at EKIN 2645 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.043.

Measured values of CNN at EKIN 2795 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.066.

Measured values of CNN at EKIN 1955 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.086.

Measured values of CNN at EKIN 1975 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.072.

Measured values of CNN at EKIN 1995 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.101.

Measured values of CNN at EKIN 2015 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.079.

Measured values of CNN at EKIN 2035 Mev (from run period I).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.070.

Measured values of CNN at EKIN 2035 Mev (from run period II).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.065.

Measured values of CNN at EKIN 2055 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.070.

Measured values of CNN at EKIN 2075 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.064.

Measured values of CNN at EKIN 2095 Mev (from run period I).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.068.

Measured values of CNN at EKIN 2095 Mev (from run period II).. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.050.

Measured values of CNN at EKIN 2115 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.071.

Measured values of CNN at EKIN 2135 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.070.

Measured values of CNN at EKIN 2155 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.067.

Measured values of CNN at EKIN 2175 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.067.

Measured values of CNN at EKIN 2205 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.073.

Measured values of CNN at EKIN 2215 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.085.

Measured values of CNN at EKIN 2225 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.070.

Measured values of CNN at EKIN 2235 Mev.. Fractional systematic uncertainty in the absolute beam and target polarization is +-0.066.

Measurements of DSL with statistical errors only.

Measurements of DSS with statistical errors only.

Measurements of KNN with statistical errors only.

Measurements of KSL with statistical errors only.

Measurements of KSS with statistical errors only.

Measurements of the triple spin parameter NNLL with statistical errors only.

Measurements of the triple spin parameter NSLN with statistical errors only.

Measurements of the triple spin parameter NSNS with statistical errors only.

Measurements of the triple spin parameter NSSN with statistical errors only.

Measurements of the spin correlation parameter CLL. Statistical errors onlyare shown. For the systematics see the systematic section above. Note the two overlapping angular settings.

Measurements of the combined spin observable Cpq measured in the (x,xz) position as a linear combination of CSS, CSL and CLL (see the table above for the coefficients). The errors are purely statistical. An extra 6 PCT uncertainty has to be added to the systematic errors shown in the systematic section above.

Measurements of the combined spin observable Cpq measured in the (x,z) position as a linear combination of CSL and CLL (see the table above for the coefficients). The errors are purely statistical. An extra 6 PCT uncertainty has to be added to the systematic errors shown in the systematic section above.

Measured values of the P P analysing power at kinetic energy 2.035 GeV fromrun II. The relative and additive systematic errors are +- 0.050 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.115 GeV. Therelative and additive systematic errors are +- 0.038 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.155 GeV. Therelative and additive systematic errors are +- 0.030 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.175 GeV. Therelative and additive systematic errors are +- 0.032 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.215 GeV. Therelative and additive systematic errors are +- 0.028 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.225 GeV. Therelative and additive systematic errors are +- 0.042 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.235 GeV. Therelative and additive systematic errors are +- 0.034 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.345 GeV. Therelative and additive systematic errors are +- 0.040 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.395 GeV. Therelative and additive systematic errors are +- 0.039 and 0.002.

Measured values of the P P analysing power at kinetic energy 2.445 GeV. Therelative and additive systematic errors are +- 0.042 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.495 GeV. Therelative and additive systematic errors are +- 0.034 and 0.002.

Measured values of the P P analysing power at kinetic energy 2.515 GeV. Therelative and additive systematic errors are +- 0.036 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.565 GeV. Therelative and additive systematic errors are +- 0.036 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.575 GeV. Therelative and additive systematic errors are +- 0.035 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.595 GeV. Therelative and additive systematic errors are +- 0.034 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.645 GeV. Therelative and additive systematic errors are +- 0.035 and 0.001.

Measured values of the P P analysing power at kinetic energy 2.795 GeV. Therelative and additive systematic errors are +- 0.061 and 0.001.