ukaea · chris-ashe · Jun 2, 2026 · Jun 2, 2026 · Jun 2, 2026 · Jun 2, 2026
@@ -237,7 +237,7 @@ The toroidal field falls off at a rate $1/R$, with the peak value occurring at t
 
 Three constraints are relevant to the operating current density $J_{\mbox{op}}$ in the TF coils.
 
-- Criticial current (`constraint 33`): $f_{\text{iooic}}J_{\mbox{op}}$ must not exceed the critical value $J_{\mbox{crit}}$ where `fiooic` is a margin on the constraint that defaults to `0.7`.
+- Criticial current (`constraint 33`): $f_{\text{iooic}}J_{\mbox{op}}$ must not exceed the critical value $J_{\mbox{crit}}$ where `f_j_tf_wp_critical_max` is a margin on the constraint that defaults to `0.7`.
 
 - Temperature margin (`constraint 36`) -- The critical current density $J_{\mbox{crit}}$ falls with 
   the temperature of the superconductor. The temperature margin $\Delta T$ is the difference between the current sharing temperature (at which $J_{\mbox{crit}}$ would be equal to $J_{\mbox{op}}$) and the operating temperature. The minimum allowed $\Delta T$

@@ -74,7 +74,7 @@ ixc = 10 * "ISS04 Renormalization Factor" (can also be fixed)
 ixc = 50 * Coil current density, aka winding pack thickness (required!) 
 ixc = 59 * Winding Pack copper fraction
 ixc = 56 * Exponential Quench Dumping Time
-ixc = 109 * Thermal alpha particle pressure (iterated to consistency, use together with `f_alpha_energy_confinement_min`)
+ixc = 109 * Thermal alpha particle pressure (iterated to consistency, use together with `f_t_alpha_energy_confinement_min`)
 ixc = 169 * Achievable Temperature of the ECRH at the ignition point
 ```
 
@@ -131,7 +131,7 @@ The density limit relevant to certain stellarators experiments has been proposed
 
 $n_{max} = 0.25(PB_0/R_0a^2_p)^{1/2}$
 
-where $n$ is the line-averaged electron density in units of $10^{20} m^{-3}$, $p$ is the absorbed heating power (MW), $B_0$ is the on-axis field (t), $R_0$ is the major radius (m), and $a_p$ is the plasma minor radius (m). To enforce the Sudo density limit, turn on constraint equation no. 5 (`fdene != 1` can be used to scale the constraint bound).
+where $n$ is the line-averaged electron density in units of $10^{20} m^{-3}$, $p$ is the absorbed heating power (MW), $B_0$ is the on-axis field (t), $R_0$ is the major radius (m), and $a_p$ is the plasma minor radius (m). To enforce the Sudo density limit, turn on constraint equation no. 5 (`f_nd_plasma_electron_limit_max != 1` can be used to scale the constraint bound).
 
 Note that the Sudo limit is a radiation based density limit and it is unclear how well this limit extrapolates to reactor parameters, especially as no impurity dependence e.g. is present in the Sudo model.
 PROCESS features an impurity dependent radiation module already which can be used with `icc=17` and by setting the `f_nd_impurity_electrons` vector.
@@ -226,7 +226,7 @@ f_a_tf_turn_cable_copper = 0.7 *Copper fraction of cable conductor (TF coils), S
 tftmp = 4.75 *Peak helium coolant temperature in TF coils and PF coils (K)
 temp_tf_cryo = 4.75 * Temperature in TF coils, required for plant efficiency (K)
 f_a_tf_turn_cable_space_extra_void = 0.3 *Coolant fraction of TF coil leg (itfsup=0) this is the same for conductor and strand!
-fiooic = 0.78 * Fraction TF coil critical current to operation current (constraint margin)
+f_j_tf_wp_critical_max = 0.78 * Fraction TF coil critical current to operation current (constraint margin)
 v_tf_coil_dump_quench_max_kv = 12.64 * Max voltage across tf coil during quench (kV)
 t_tf_superconductor_quench = 20 * Dump time (should be iteration variable)
 dr_tf_nose_case = 0.1 * Thickness TF Coil case (for stellarators: Also for toroidal direction)

@@ -705,7 +705,7 @@ The constraint uses the loss power and thermal densities hence the inclusion of
 
 This constraint can be activated by stating `icc = 62` in the input file.
 
-The value of `f_alpha_energy_confinement_min` can be set to the desired minimum total ratio between the alpha confinement and energy confinement times.
+The value of `f_t_alpha_energy_confinement_min` can be set to the desired minimum total ratio between the alpha confinement and energy confinement times.
 
 [^1]: N. A. Uckan, International Atomic Energy Agency, Vienna (Austria) and ITER Physics Group, "ITER physics design guidelines: 1989", no. No. 10. Feb. 1990.
 [^2]: T.C. Hender et al., 'Physics Assessment of the European Reactor Study', AEA FUS 172, 1992.

@@ -5,7 +5,7 @@ calculated in the run routine `density_limit.run()`, which is called by `physics
 
 This constraint can be activated by stating `icc = 5` in the input file.
 
-The value of `i_density_limit` can be set to apply the relevant limit. The variable `fdene` can be set to scale the constraint bound: `nd_plasma_electrons_vol_avg` / `nd_plasma_electrons_max` <= `fdene` (or `nd_plasma_electron_line` / `nd_plasma_electrons_max` <= `fdene` if `i_density_limit = 7`).
+The value of `i_density_limit` can be set to apply the relevant limit. The variable `f_nd_plasma_electron_limit_max` can be set to scale the constraint bound: `nd_plasma_electrons_vol_avg` / `nd_plasma_electrons_max` <= `f_nd_plasma_electron_limit_max` (or `nd_plasma_electron_line` / `nd_plasma_electrons_max` <= `f_nd_plasma_electron_limit_max` if `i_density_limit = 7`).
 
 For the `i_density_limit = 1-5,8` scalings we scale the function output by the separatrix to volume averaged electron density so that we can set the limit on the volume averaged. **Therefore it is recommended to only use these scalings with an H-mode profile (`i_plasma_pedestal == 1`) otherwise the separatrix density (`nd_plasma_separatrix_electron`) will not be calculated.**
 

@@ -107,7 +107,7 @@ temp_cs_superconductor_margin_min = 1.5
 * Lower limit on f_alpha_energy_confinement (ratio alpha particle/energy confinement times) *
 *-------------------------------------------------------------------------------*
 icc = 62 
-f_alpha_energy_confinement_min = 5.0
+f_t_alpha_energy_confinement_minin = 5.0
 
 * dump time constraint for VV stresses *
 *--------------------------------------*
@@ -128,7 +128,7 @@ icc = 81
 *------------------*
 
 icc = 68
-psepbqarmax = 10.0
+p_div_bt_q_aspect_rmajor_max_mwaspect_rmajor_max_mw = 10.0
 
 * TF coil stress limits *
 *-----------------------*
@@ -572,4 +572,4 @@ f_a_tf_turn_cable_space_extra_void = 0.3
 i_tf_sc_mat = 1
 
 * max fluence in the TF coil
-nflutfmax = 1e22
+flu_tf_neutron_fast_maxutron_fast_max = 1e22
@@ -92,16 +92,16 @@ dr_shld_blkt_gap  = 0.02 * gap between vacuum vessel and blanket (m)
 *---------------Constraint Variables---------------*
 
 b_tf_inboard_max   = 14.0 * maximum peak toroidal field (T) (`constraint equation 25`)
-fdene    = 1.2 * density limit constraint scale (constraint equation 5)
-fiooic   = 0.65 * margin for TF coil operating current / critical current ratio
+f_nd_plasma_electron_limit_max    = 1.2 * density limit constraint scale (constraint equation 5)
+f_j_tf_wp_critical_max_wp_critical_max   = 0.65 * margin for TF coil operating current / critical current ratio
 fjohc    = 0.6 * margin for central solenoid current at end-of-flattop
 fjohc0   = 0.6 * margin for central solenoid current at beginning of pulse
 p_plant_electric_net_required_mw = 400.0 * required net electric power (MW) (`constraint equation 16`)
 p_fusion_total_max_mw  = 3000 * maximum fusion power (MW) (`constraint equation 9`)
-psepbqarmax = 10.0 * maximum ratio of Psep*Bt/qAR (MWT/m) (`constraint equation 68`)
+p_div_bt_q_aspect_rmajor_max_mw = 10.0 * maximum ratio of Psep*Bt/qAR (MWT/m) (`constraint equation 68`)
 t_burn_min   = 7200.0 * minimum burn time (s) (KE - no longer itv;; see issue #706)
 pflux_fw_neutron_max_mw   = 2.0 * allowable neutron wall-load (MW/m2) (`constraint equation 8`)
-f_alpha_energy_confinement_min = 5.0 * Lower limit on f_alpha_energy_confinement the ratio of alpha particle to energy confinement
+f_t_alpha_energy_confinement_min = 5.0 * Lower limit on f_t_alpha_energy_confinementnt the ratio of alpha particle to energy confinement
 
 *-------------------Constraints--------------------*
 

@@ -104,10 +104,10 @@ tmargmin = 1.5
 icc = 60
 temp_cs_superconductor_margin_min = 1.5
 
-* Lower limit on f_alpha_energy_confinement (ratio alpha particle/energy confinement times) *
+* Lower limit on f_t_alpha_energy_confinement (ratio alpha particle/energy confinement times) *
 *-------------------------------------------------------------------------------*
 icc = 62 
-f_alpha_energy_confinement_min = 5.0
+f_t_alpha_energy_confinement_min = 5.0
 
 * dump time constraint for VV stresses *
 *--------------------------------------*
@@ -128,7 +128,7 @@ icc = 81
 *------------------*
 
 icc = 68
-psepbqarmax = 10.0
+p_div_bt_q_aspect_rmajor_max_mw = 10.0
 
 * TF coil stress limits *
 *-----------------------*
@@ -572,4 +572,4 @@ f_a_tf_turn_cable_space_extra_void = 0.3
 i_tf_sc_mat = 1
 
 * max fluence in the TF coil
-nflutfmax = 1e22
+flu_tf_neutron_fast_maxutron_fast_max = 1e22
@@ -104,10 +104,10 @@ tmargmin = 1.5
 icc = 60
 temp_cs_superconductor_margin_min = 1.5
 
-* Lower limit on f_alpha_energy_confinement (ratio alpha particle/energy confinement times) *
+* Lower limit on f_t_alpha_energy_confinement (ratio alpha particle/energy confinement times) *
 *-------------------------------------------------------------------------------*
 icc = 62 
-f_alpha_energy_confinement_min = 5.0
+f_t_alpha_energy_confinement_min = 5.0
 
 * dump time constraint for VV stresses *
 *--------------------------------------*
@@ -128,7 +128,7 @@ icc = 81
 *------------------*
 
 icc = 68
-psepbqarmax = 10.0
+p_div_bt_q_aspect_rmajor_max_mw = 10.0
 
 * TF coil stress limits *
 *-----------------------*
@@ -572,4 +572,4 @@ f_a_tf_turn_cable_space_extra_void = 0.3
 i_tf_sc_mat = 1
 
 * max fluence in the TF coil
-nflutfmax = 1e22
+flu_tf_neutron_fast_maxutron_fast_max = 1e22
@@ -118,7 +118,7 @@ temp_cs_superconductor_margin_min = 1.5
 * Lower limit on f_alpha_energy_confinement (ratio alpha particle/energy confinement times) *
 *-------------------------------------------------------------------------------*
 icc = 62 
-f_alpha_energy_confinement_min = 5.0
+f_t_alpha_energy_confinement_minin = 5.0
 
 * dump time constraint for VV stresses *
 *--------------------------------------*
@@ -138,7 +138,7 @@ icc = 81
 *------------------*
 
 icc = 68
-psepbqarmax = 10.0
+p_div_bt_q_aspect_rmajor_max_mwaspect_rmajor_max_mw = 10.0
 
 * TF coil stress limits *
 *-----------------------*
@@ -582,4 +582,4 @@ f_a_tf_turn_cable_space_extra_void = 0.3
 i_tf_sc_mat = 1
 
 * max fluence in the TF coil
-nflutfmax = 1e22
+flu_tf_neutron_fast_maxutron_fast_max = 1e22
@@ -269,8 +269,7 @@
 """Density of Tungsten [kg/m3]"""
 
 TEMP_ROOM = 293.15
-""" Room temperature in Kelvin
-Assume the room is at 20 degrees Celsius
+""" Room temperature in Kelvin. Assuming the room is at 20 degrees Celsius
 """
 
 RMU0 = 1.256637062e-6

@@ -165,15 +165,15 @@ def __post_init__(self):
     "alstroh": InputVariable("pf_coil", float, range=(1000000.0, 100000000000.0)),
     "amortization": InputVariable("costs", float, range=(1.0, 50.0)),
     "anginc": InputVariable("divertor", float, range=(0.0, 1.5707)),
-    "aplasmin": InputVariable("build", float, range=(0.01, 10.0)),
+    "rminor_min": InputVariable("build", float, range=(0.01, 10.0)),
     "aux_build_h": InputVariable("buildings", float, range=(1.0, 100.0)),
     "aux_build_l": InputVariable("buildings", float, range=(10.0, 1000.0)),
     "aux_build_w": InputVariable("buildings", float, range=(10.0, 1000.0)),
     "auxcool_h": InputVariable("buildings", float, range=(1.0, 100.0)),
     "auxcool_l": InputVariable("buildings", float, range=(10.0, 1000.0)),
     "auxcool_w": InputVariable("buildings", float, range=(10.0, 1000.0)),
     "p_hcd_injected_min_mw": InputVariable("constraints", float, range=(0.01, 100.0)),
-    "avail_min": InputVariable("costs", float, range=(0.0, 1.0)),
+    "f_t_plant_available_min": InputVariable("costs", float, range=(0.0, 1.0)),
     "b_crit_upper_nbti": InputVariable("tfcoil", float, range=(0.0, 30.0)),
     "p_plant_electric_base": InputVariable(
         "heat_transport", float, range=(1000000.0, 10000000000.0)
@@ -381,7 +381,7 @@ def __post_init__(self):
         "tfcoil", float, range=(100000000.0, 10000000000000.0)
     ),
     "f_a_tf_cool_outboard": InputVariable("tfcoil", float, range=(0.0, 1.0)),
-    "f_alpha_energy_confinement_min": InputVariable(
+    "f_t_alpha_energy_confinement_min": InputVariable(
         "constraints", float, range=(1.0, 100.0)
     ),
     "f_asym": InputVariable("stellarator", float, range=(0.9, 2.0)),
@@ -428,8 +428,10 @@ def __post_init__(self):
     "fcuohsu": InputVariable("pf_coil", float, range=(0.0, 1.0)),
     "fcupfsu": InputVariable("pf_coil", float, range=(0.0, 1.0)),
     "f_a_tf_turn_cable_copper": InputVariable("tfcoil", float, range=(0.0, 1.0)),
-    "fdene": InputVariable("constraints", float, range=(0.001, 10.0)),
-    "fiooic": InputVariable("constraints", float, range=(0.001, 1.0)),
+    "f_nd_plasma_electron_limit_max": InputVariable(
+        "constraints", float, range=(0.001, 10.0)
+    ),
+    "f_j_tf_wp_critical_max": InputVariable("constraints", float, range=(0.001, 1.0)),
     "fjohc": InputVariable("constraints", float, range=(0.001, 1.0)),
     "fjohc0": InputVariable("constraints", float, range=(0.001, 1.0)),
     "fdiva": InputVariable("divertor", float, range=(0.1, 2.0)),
@@ -460,7 +462,9 @@ def __post_init__(self):
         "heat_transport", float, range=(0.0, 0.2)
     ),
     "fracture_toughness": InputVariable("cs_fatigue", float, range=(0.1, 100000000.0)),
-    "fradpwr": InputVariable("constraints", float, range=(0.0, 1.0)),
+    "f_p_plasma_separatrix_rad_max": InputVariable(
+        "constraints", float, range=(0.0, 1.0)
+    ),
     "f_radius_beam_tangency_rmajor": InputVariable(
         "current_drive", float, range=(0.5, 2.0)
     ),
@@ -584,7 +588,7 @@ def __post_init__(self):
     "i_nd_plasma_pedestal_separatrix": InputVariable(
         data_structure.physics_variables, int, choices=[0, 1]
     ),
-    "nflutfmax": InputVariable("constraints", float, range=(0.0, 1e24)),
+    "flu_tf_neutron_fast_max": InputVariable("constraints", float, range=(0.0, 1e24)),
     "j_tf_coil_full_area": InputVariable("tfcoil", float, range=(10000.0, 1000000000.0)),
     "f_a_cs_turn_steel": InputVariable("pf_coil", float, range=(0.001, 0.999)),
     "f_z_cs_tf_internal": InputVariable("pf_coil", float, range=(0.0, 2.0)),
@@ -632,8 +636,12 @@ def __post_init__(self):
     "pres_div_chamber_burn": InputVariable("vacuum", float, range=(0.0, 10.0)),
     "pres_fw_coolant": InputVariable("fwbs", float, range=(100000.0, 100000000.0)),
     "prn1": InputVariable("divertor", float, range=(0.0, 1.0)),
-    "psepbqarmax": InputVariable("constraints", float, range=(1.0, 50.0)),
-    "pseprmax": InputVariable("constraints", float, range=(1.0, 60.0)),
+    "p_div_bt_q_aspect_rmajor_max_mw": InputVariable(
+        "constraints", float, range=(1.0, 50.0)
+    ),
+    "p_plasma_separatrix_rmajor_max_mw": InputVariable(
+        "constraints", float, range=(1.0, 60.0)
+    ),
     "ptargf": InputVariable("ife", float, range=(0.1, 100.0)),
     "temp_cp_max": InputVariable("tfcoil", float, range=(4.0, 573.15)),
     "ptfnucmax": InputVariable("constraints", float, range=(1e-06, 1.0)),
@@ -934,7 +942,9 @@ def __post_init__(self):
     "wsvfac": InputVariable("buildings", float, range=(0.9, 3.0)),
     "xi_ebw": InputVariable("current_drive", float, range=(0.0, 1.0)),
     "xpertin": InputVariable("divertor", float, range=(0.0, 10.0)),
-    "zeff_max": InputVariable("constraints", float, range=(1.0, 10.0)),
+    "n_charge_plasma_effective_vol_avg_max": InputVariable(
+        "constraints", float, range=(1.0, 10.0)
+    ),
     "blktmodel": InputVariable("fwbs", int, choices=[0, 1]),
     "blkttype": InputVariable("fwbs", int, choices=[1, 2, 3]),
     "breedmat": InputVariable("fwbs", int, choices=[1, 2, 3]),

@@ -182,7 +182,7 @@
     "d_vv_in": "dr_vv_inboard",
     "d_vv_out": "dr_vv_outboard",
     "iblnkith": "i_blkt_inboard",
-    "taulimit": "f_alpha_energy_confinement_min",
+    "taulimit": "f_t_alpha_energy_confinement_min",
     "isc": "i_confinement_time",
     "iradloss": "i_rad_loss",
     "iinvqd": None,
@@ -360,7 +360,7 @@
     "tmax_croco": "temp_croco_quench_max",
     "vdalw": "v_tf_coil_dump_quench_max_kv",
     "vvhealw": None,
-    "zeffmax": "zeff_max",
+    "zeffmax": "n_charge_plasma_effective_vol_avg_max",
     "f_a_fw_hcd": "f_a_fw_outboard_hcd",
     "fpumpblkt": "f_p_blkt_coolant_pump_total_heat",
     "fpumpshld": "f_p_shld_coolant_pump_total_heat",
@@ -457,6 +457,15 @@
     "dr_hts_tape": "dr_tf_hts_tape",
     "coppera_m2_max": "tf_coppera_m2_max",
     "f_ster_div_single": None,
+    "fradpwr": "f_p_plasma_separatrix_rad_max",
+    "aplasmin": "rminor_min",
+    "nflutfmax": "flu_tf_neutron_fast_max",
+    "pseprmax": "p_plasma_separatrix_rmajor_max_mw",
+    "avail_min": "f_t_plant_available_min",
+    "f_alpha_energy_confinement_min": "f_t_alpha_energy_confinement_min",
+    "zeff_max": "n_charge_plasma_effective_vol_avg_max",
+    "psepbqarmax": "p_div_bt_q_aspect_rmajor_max_mw",
+    "fdene": "f_nd_plasma_electron_limit_max",
 }
 
 OBS_VARS_HELP = {

@@ -91,7 +91,7 @@ def plot_scan(
         11: "beta_norm_max",
         12: "f_c_plasma_bootstrap_max",
         13: "boundu(10)",
-        14: "fiooic",
+        14: "f_j_tf_wp_critical_max",
         16: "rmajor",
         17: "b_tf_inboard_peak_symmetric",  # b_tf_inboard_max the maximum T field upper limit is the scan variable
         18: "eta_cd_norm_hcd_primary_max",
@@ -107,7 +107,7 @@ def plot_scan(
         28: "b_plasma_toroidal_on_axis",
         29: "radius_plasma_core_norm",
         30: "",  # OBSOLETE
-        31: "f_alpha_energy_confinement_min",
+        31: "f_t_alpha_energy_confinement_min",
         32: "epsvmc",
         33: "ttarget",
         34: "qtargettotal",

@@ -2817,7 +2817,7 @@ def plot_main_plasma_information(
         f"Lawson Triple product: {mfile.get('nttau', scan=scan):.4e} keV·s/m³\n"
         f"Transport loss power assumed in scaling law: {mfile.get('p_plasma_loss_mw', scan=scan):.4f} MW\n"
         f"Plasma thermal energy (inc. $\\alpha$), $W$: {mfile.get('e_plasma_beta', scan=scan) / 1e9:.4f} GJ\n"
-        f"Alpha particle confinement time: {mfile.get('t_alpha_confinement', scan=scan):.4f} s | $\\tau_{{\\alpha}}/\\tau_{{e}}$: {mfile.get('f_alpha_energy_confinement', scan=scan):.4f}"
+        f"Alpha particle confinement time: {mfile.get('t_alpha_confinement', scan=scan):.4f} s | $\\tau_{{\\alpha}}/\\tau_{{e}}$: {mfile.get('f_t_alpha_energy_confinement', scan=scan):.4f}"
     )
 
     axis.text(
@@ -15563,7 +15563,7 @@ def main_plot(
                 temp_quench_max=m_file.get("temp_tf_conductor_quench_max", scan=scan),
                 cu_rrr=m_file.get("rrr_tf_cu", scan=scan),
                 t_quench_detection=m_file.get("t_tf_quench_detection", scan=scan),
-                fluence=m_file.get("nflutfmax", scan=scan),
+                fluence=m_file.get("flu_tf_neutron_fast_max", scan=scan),
                 j_operating=m_file.get("j_tf_wp", scan=scan),
                 a_tf_turn_cable_space=m_file.get(
                     "a_tf_turn_cable_space_no_void", scan=scan

@@ -54,7 +54,7 @@ class VariableMetadata:
         description="Average electron temperature",
         units="keV",
     ),
-    "f_alpha_energy_confinement_min": VariableMetadata(
+    "f_t_alpha_energy_confinement_min": VariableMetadata(
         latex=r"$max : \frac{\tau_\mathrm{\alpha}}{\tau_\mathrm{E}}$",
         description="Ratio of alpha heating time to energy confinement time",
         units="",