<profiles_1d>
  <psi>{1,1}</psi>
  <phi>{1,1}</phi>
  <pressure>{1,1}</pressure>
  <F_dia>{1,1}</F_dia>
  <pprime>{1,1}</pprime>
  <ffprime>{1,1}</ffprime>
  <jphi>{1,1}</jphi>
  <jparallel>{1,1}</jparallel>
  <q>{1,1}</q>
  <shear>{1,1}</shear>
  <r_inboard>{1,1}</r_inboard>
  <r_outboard>{1,1}</r_outboard>
  <rho_tor>{1,1}</rho_tor>
  <dpsidrho_tor>{1,1}</dpsidrho_tor>
  <rho_vol>{1,1}</rho_vol>
  <beta_pol>{1,1}</beta_pol>
  <li>{1,1}</li>
  <elongation>{1,1}</elongation>
  <tria_upper>{1,1}</tria_upper>
  <tria_lower>{1,1}</tria_lower>
  <volume>{1,1}</volume>
  <vprime>{1,1}</vprime>
  <dvdrho>{1,1}</dvdrho>
  <area>{1,1}</area>
  <aprime>{1,1}</aprime>
  <surface>{1,1}</surface>
  <ftrap>{1,1}</ftrap>
  <gm1>{1,1}</gm1>
  <gm2>{1,1}</gm2>
  <gm3>{1,1}</gm3>
  <gm4>{1,1}</gm4>
  <gm5>{1,1}</gm5>
  <gm6>{1,1}</gm6>
  <gm7>{1,1}</gm7>
  <gm8>{1,1}</gm8>
  <gm9>{1,1}</gm9>
  <b_av>{1,1}</b_av>
  <b_min>{1,1}</b_min>
  <b_max>{1,1}</b_max>
  <omega>{1,1}</omega>
  <omegaprime>{1,1}</omegaprime>
  <mach_a>{1,1}</mach_a>
  <phi_flow>{1,1}</phi_flow>
  <s_flow>{1,1}</s_flow>
  <h_flow>{1,1}</h_flow>
  <rho_mass>{1,1}</rho_mass>
</profiles_1d>

<xs:element name="profiles_1d">
  <xs:annotation>
    <xs:documentation>output profiles as a function of the poloidal flux</xs:documentation>
  </xs:annotation>
  <xs:complexType>
    <xs:sequence>
      <xs:element name="psi" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Poloidal flux [Wb], without 1/2pi and such that Bp=|grad psi| /R/2/pi. Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="phi" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>toroidal flux [Wb]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="pressure" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>pressure profile as a function of the poloidal flux [Pa]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
          <xs:appinfo>representation name=f_psi; var=scalar; meshtype=axis1D0; link1=profiles_1d/psi;</xs:appinfo>
          <xs:appinfo>representation name=f_phi; var=scalar; meshtype=axis1D0; link1=profiles_1d/phi;</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="F_dia" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>diamagnetic profile (R B_phi) [T m]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="pprime" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>psi derivative of the pressure profile [Pa/Wb]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="ffprime" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>psi derivative of F_dia multiplied with F_dia [T^2 m^2/Wb]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="jphi" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>flux surface averaged toroidal current density = average(jphi/R) / average(1/R) [A/m^2]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="jparallel" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>flux surface averaged parallel current density = average(j.B) / B0, where B0 = equilibrium/global_param/toroid_field/b0 ; [A/m^2]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="q" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Safety factor = dphi/dpsi [-]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="shear" type="vecflt_type">
        <xs:annotation>
          <xs:appinfo>experimental</xs:appinfo>
          <xs:documentation>Magnetic shear, defined as rho_tor/q*dq/drho_tor [-]; Time-dependent; Vector (npsi)</xs:documentation>
        </xs:annotation>
      </xs:element>
      <xs:element name="r_inboard" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>radial coordinate (major radius) at the height and on the left of the magnetic axis [m]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="r_outboard" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>radial coordinate (major radius) at the height and on the right of the magnetic axis [m]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="rho_tor" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Toroidal flux coordinate [m], to be used by the ETS and in many CPOs (coreprof, ...). Defined as sqrt(phi/pi/B0), where B0 = equilibrium/global_param/toroid_field/b0. Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="dpsidrho_tor" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>dpsi/drho_tor [Wb/m]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="rho_vol" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Normalised radial coordinate related to the plasma volume. Defined as sqrt(volume / volume[LCFS]). Time-dependent; Vector (npsi)</xs:documentation>
        </xs:annotation>
      </xs:element>
      <xs:element name="beta_pol" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>poloidal beta (inside the magnetic surface); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="li" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>internal inductance (inside the magnetic surface); Time-dependent; Vector (npsi)</xs:documentation>
        </xs:annotation>
      </xs:element>
      <xs:element name="elongation" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Elongation; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="tria_upper" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Upper triangularity profile; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="tria_lower" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Lower triangularity profile; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="volume" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Volume enclosed in the flux surface [m^3]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="vprime" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Radial derivative of the volume enclosed in the flux surface with respect to psi, i.e. dV/dpsi [m^3/Wb]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="dvdrho" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Radial derivative of the volume enclosed in the flux surface with respect to rho_tor, i.e. dV/drho_tor [m^2]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="area" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Cross-sectional area of the flux surface [m^2]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="aprime" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Radial derivative of the cross-sectional area of the flux surface with respect to psi, i.e. darea/dpsi [m^2/Wb]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="surface" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Surface area of the flux surface [m^2]; Time-dependent; Vector (npsi)</xs:documentation>
        </xs:annotation>
      </xs:element>
      <xs:element name="ftrap" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Trapped particle fraction; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm1" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(1/R^2); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm2" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(grad_rho^2/R^2); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm3" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(grad_rho^2); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm4" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(1/B^2) [T^-2]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm5" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(B^2) [T^2]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm6" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(grad_rho^2/B^2) [T^-2]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm7" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(grad_rho); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm8" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(R); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="gm9" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(1/R); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="b_av" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>average(B); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="b_min" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>minimum(B) on the flux surface; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="b_max" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>maximum(B) on the flux surface; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="omega" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Toroidal rotation angular frequency (assumed constant on the flux surface) [rad/s]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="omegaprime" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Psi derivative of the toroidal rotation angular frequency (assumed constant on the flux surface) [rad/(s.Wb)]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="mach_a" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Alfvenic Mach number; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="phi_flow" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Poloidal flow function phi_flow = rho*v_pol/B_pol[kg/(V.s^2)] where rho is mass density; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="s_flow" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Flux function in the closure equation p=S(psi).rho^(gamma); Entropy (gamma=5/3) or Temperature (gamma=1); Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="h_flow" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>flow function h_flow = gamma/(gamma-1)*s_flow*rho^(gamma-1) + 0.5*(phi_flow*B/rho)^2 - 0.5*(R*omega)^2 [m^2/s^2]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
      <xs:element name="rho_mass" type="vecflt_type">
        <xs:annotation>
          <xs:documentation>Mass density [kg/m^3]; Time-dependent; Vector (npsi)</xs:documentation>
          <xs:appinfo>experimental</xs:appinfo>
        </xs:annotation>
      </xs:element>
    </xs:sequence>
  </xs:complexType>
</xs:element>

<xs:element name="psi" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Poloidal flux [Wb], without 1/2pi and such that Bp=|grad psi| /R/2/pi. Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="phi" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>toroidal flux [Wb]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="pressure" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>pressure profile as a function of the poloidal flux [Pa]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
    <xs:appinfo>representation name=f_psi; var=scalar; meshtype=axis1D0; link1=profiles_1d/psi;</xs:appinfo>
    <xs:appinfo>representation name=f_phi; var=scalar; meshtype=axis1D0; link1=profiles_1d/phi;</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="F_dia" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>diamagnetic profile (R B_phi) [T m]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="pprime" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>psi derivative of the pressure profile [Pa/Wb]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="ffprime" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>psi derivative of F_dia multiplied with F_dia [T^2 m^2/Wb]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="jphi" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>flux surface averaged toroidal current density = average(jphi/R) / average(1/R) [A/m^2]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="jparallel" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>flux surface averaged parallel current density = average(j.B) / B0, where B0 = equilibrium/global_param/toroid_field/b0 ; [A/m^2]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="q" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Safety factor = dphi/dpsi [-]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="shear" type="vecflt_type">
  <xs:annotation>
    <xs:appinfo>experimental</xs:appinfo>
    <xs:documentation>Magnetic shear, defined as rho_tor/q*dq/drho_tor [-]; Time-dependent; Vector (npsi)</xs:documentation>
  </xs:annotation>
</xs:element>

<xs:element name="r_inboard" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>radial coordinate (major radius) at the height and on the left of the magnetic axis [m]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="r_outboard" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>radial coordinate (major radius) at the height and on the right of the magnetic axis [m]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="rho_tor" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Toroidal flux coordinate [m], to be used by the ETS and in many CPOs (coreprof, ...). Defined as sqrt(phi/pi/B0), where B0 = equilibrium/global_param/toroid_field/b0. Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="dpsidrho_tor" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>dpsi/drho_tor [Wb/m]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="rho_vol" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Normalised radial coordinate related to the plasma volume. Defined as sqrt(volume / volume[LCFS]). Time-dependent; Vector (npsi)</xs:documentation>
  </xs:annotation>
</xs:element>

<xs:element name="beta_pol" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>poloidal beta (inside the magnetic surface); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="li" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>internal inductance (inside the magnetic surface); Time-dependent; Vector (npsi)</xs:documentation>
  </xs:annotation>
</xs:element>

<xs:element name="elongation" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Elongation; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="tria_upper" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Upper triangularity profile; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="tria_lower" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Lower triangularity profile; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="volume" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Volume enclosed in the flux surface [m^3]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="vprime" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Radial derivative of the volume enclosed in the flux surface with respect to psi, i.e. dV/dpsi [m^3/Wb]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="dvdrho" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Radial derivative of the volume enclosed in the flux surface with respect to rho_tor, i.e. dV/drho_tor [m^2]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="area" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Cross-sectional area of the flux surface [m^2]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="aprime" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Radial derivative of the cross-sectional area of the flux surface with respect to psi, i.e. darea/dpsi [m^2/Wb]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="surface" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Surface area of the flux surface [m^2]; Time-dependent; Vector (npsi)</xs:documentation>
  </xs:annotation>
</xs:element>

<xs:element name="ftrap" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Trapped particle fraction; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm1" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(1/R^2); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm2" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(grad_rho^2/R^2); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm3" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(grad_rho^2); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm4" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(1/B^2) [T^-2]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm5" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(B^2) [T^2]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm6" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(grad_rho^2/B^2) [T^-2]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm7" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(grad_rho); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm8" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(R); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="gm9" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(1/R); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="b_av" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>average(B); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="b_min" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>minimum(B) on the flux surface; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="b_max" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>maximum(B) on the flux surface; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="omega" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Toroidal rotation angular frequency (assumed constant on the flux surface) [rad/s]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="omegaprime" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Psi derivative of the toroidal rotation angular frequency (assumed constant on the flux surface) [rad/(s.Wb)]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="mach_a" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Alfvenic Mach number; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="phi_flow" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Poloidal flow function phi_flow = rho*v_pol/B_pol[kg/(V.s^2)] where rho is mass density; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="s_flow" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Flux function in the closure equation p=S(psi).rho^(gamma); Entropy (gamma=5/3) or Temperature (gamma=1); Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="h_flow" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>flow function h_flow = gamma/(gamma-1)*s_flow*rho^(gamma-1) + 0.5*(phi_flow*B/rho)^2 - 0.5*(R*omega)^2 [m^2/s^2]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>

<xs:element name="rho_mass" type="vecflt_type">
  <xs:annotation>
    <xs:documentation>Mass density [kg/m^3]; Time-dependent; Vector (npsi)</xs:documentation>
    <xs:appinfo>experimental</xs:appinfo>
  </xs:annotation>
</xs:element>