How to use the torchdiffeq._impl.misc._optimal_step_size function in torchdiffeq

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github uncbiag / easyreg / torchdiffeq / _impl / dopri5.py View on Github external
print(" non-finite elements exist, try to fix")
                y0_[y0_ != y0_] = 0.
                y0_[y0_ == float("Inf")] = 0.

        y1, f1, y1_error, k = _runge_kutta_step(self.func, y0, f0, t0, dt, tableau=_DORMAND_PRINCE_SHAMPINE_TABLEAU)

        ########################################################
        #                     Error Ratio                      #
        ########################################################
        mean_sq_error_ratio = _compute_error_ratio(y1_error, atol=self.atol, rtol=self.rtol, y0=y0, y1=y1)
        accept_step = (torch.tensor(mean_sq_error_ratio) <= 1).all()

        ########################################################
        #                   Update RK State                    #
        ########################################################
        dt_next = _optimal_step_size(
            dt, mean_sq_error_ratio, safety=self.safety, ifactor=self.ifactor, dfactor=self.dfactor, order=5)
        if not (dt_next<0.02): #not (dt_next<0.02 or dt_next>0.1):
            y_next = y1 if accept_step else y0
            f_next = f1 if accept_step else f0
            t_next = t0 + dt if accept_step else t0
            interp_coeff = _interp_fit_dopri5(y0, y1, k, dt) if accept_step else interp_coeff
        else:
            if dt_next<0.02:
                print("warning the step of dopri5 {} is too small, set to 0.01".format(dt_next))
                dt_next = _convert_to_tensor(0.01, dtype=torch.float64, device=y0[0].device)
            if dt_next>0.1:
                print("warning the step of dopri5 {} is too big, set to 0.1".format(dt_next))
                dt_next = _convert_to_tensor(0.1, dtype=torch.float64, device=y0[0].device)
            y_next = y1
            f_next = f1
            t_next = t0 + dt
github rtqichen / torchdiffeq / torchdiffeq / _impl / adaptive_heun.py View on Github external
y1, f1, y1_error, k = _runge_kutta_step(self.func, y0, f0, t0, dt, tableau=_ADAPTIVE_HEUN_TABLEAU)

        ########################################################
        #                     Error Ratio                      #
        ########################################################
        mean_sq_error_ratio = _compute_error_ratio(y1_error, atol=self.atol, rtol=self.rtol, y0=y0, y1=y1)
        accept_step = (torch.tensor(mean_sq_error_ratio) <= 1).all()

        ########################################################
        #                   Update RK State                    #
        ########################################################
        y_next = y1 if accept_step else y0
        f_next = f1 if accept_step else f0
        t_next = t0 + dt if accept_step else t0
        interp_coeff = _interp_fit_adaptive_heun(y0, y1, k, dt) if accept_step else interp_coeff
        dt_next = _optimal_step_size(
            dt, mean_sq_error_ratio, safety=self.safety, ifactor=self.ifactor, dfactor=self.dfactor, order=5
        )
        rk_state = _RungeKuttaState(y_next, f_next, t0, t_next, dt_next, interp_coeff)
        return rk_state