1. Introduction
Controlling 3-D wake dynamics holds significant importance in aerospace engineering, especially in shaping the capabilities of future aircraft. One of the challenges in flow control involves managing massively separated 3-D flows, as those observed behind finite-span wings at high angles of attack (Taira & Colonius Reference Taira and Colonius2009b; Anderson Reference Anderson2010). Traditionally, aircraft operation under stalled flow conditions is avoided due to the detrimental effects associated with flow separation. Nevertheless, many studies have shown that biological flyers and swimmers benefit from stall under certain conditions (Ellington et al. Reference Ellington, Van Den Berg, Willmott and Thomas1996; Videler, Stamhuis & Povel Reference Videler, Stamhuis and Povel2004; Shyy et al. Reference Shyy, Lian, Tang, Viieru and Liu2008; Eldredge & Jones Reference Eldredge and Jones2019). Moreover, for low-Reynolds-number flows over low-aspect-ratio wings, both lift and lift-to-drag ratio increase with the angle of attack within a certain range, even in the presence of a separation bubble (Okamoto & Azuma Reference Okamoto and Azuma2011; Ananda, Sukumar & Selig Reference Ananda, Sukumar and Selig2015; Mizoguchi, Kajikawa & Itoh Reference Mizoguchi, Kajikawa and Itoh2016; Okamoto et al. Reference Okamoto, Sasaki, Kamikubo and Fujii2019). This suggests potential benefits in exploring the flight operation of aircraft in stalled flow conditions once a flow control capable of enhancing the aerodynamics of wings at high angles of attack is identified.
Recent studies extensively delved into the fundamental characteristics of the separated wake around wings through experiments, computations and theoretical analyses, primarily focusing on the low-Reynolds-number regime (He et al. Reference He, Gioria, Pérez and Theofilis2017; Zhang et al. Reference Zhang, Hayostek, Amitay, He, Theofilis and Taira2020b; Burtsev et al. Reference Burtsev, He, Hayostek, Zhang, Theofilis, Taira and Amitay2022; Hayostek et al. Reference Hayostek, Ottinger, Neal and Amitay2022; Pandi & Mittal Reference Pandi and Mittal2023; Ribeiro, Yeh & Taira Reference Ribeiro, Yeh and Taira2023b), thereby enhancing our understanding even for much higher-Reynolds-number flows. However, limited research has been conducted on controlling and modifying stalled flow behaviour to enhance wing aerodynamics at high incidence angles (Taira & Colonius Reference Taira and Colonius2009a; Gopalakrishnan Meena, Taira & Asai Reference Gopalakrishnan Meena, Taira and Asai2017; Edstrand et al. Reference Edstrand, Sun, Schmid, Taira and Cattafesta2018b; Nastro et al. Reference Nastro, Robinet, Loiseau, Passaggia and Mazellier2023).
To improve the aerodynamic performance of wings, qualitatively evaluated as the lift-to-drag ratio, effective flow control strategies require a detailed study of load generation mechanisms. Given the particular case of stalled flows over low-aspect-ratio wings, a significant portion of lift originates from near-wake vortices around the wing (Lee et al. Reference Lee, Hsieh, Chang and Chu2012; Zhang et al. Reference Zhang, Hayostek, Amitay, He, Theofilis and Taira2020b; Ribeiro et al. Reference Ribeiro, Yeh, Zhang and Taira2022, Reference Ribeiro, Neal, Burtsev, Amitay, Theofilis and Taira2023a; Zhang & Taira Reference Zhang and Taira2022). However, due to the massive separation bubble over wings at high angles of attack, coherent structures associated with vortical lift tend to advect away from the wing, substantially reducing their contribution to the overall lift.
The reversed flow appears on the suction side of the wing for separated flows at high angles of attack (Pauley, Moin & Reynolds Reference Pauley, Moin and Reynolds1990; Yarusevych, Sullivan & Kawall Reference Yarusevych, Sullivan and Kawall2009; Toppings & Yarusevych Reference Toppings and Yarusevych2022). To suppress this vortical formation and reattach the flow, boundary-layer control approaches using unsteady actuation exciting the shear layer instabilities can be efficient (Seifert, Darabi & Wygnanski Reference Seifert, Darabi and Wygnanski1996; Greenblatt & Wygnanski Reference Greenblatt and Wygnanski2000; Amitay & Glezer Reference Amitay and Glezer2002). For the low-Reynolds-number flow regime, suppression of the separation bubble impedes the formation of large-scale lift-related vortices around the wing. Moreover, identifying the optimal spatial–temporal characteristics of the control input to achieve a specific goal is non-trivial. Flow control effects depend on flow field characteristics, which are strongly associated with the wing planform geometry.
For untapered unswept wings, the reversed-flow bubble is larger inboard near the wing root, where spanwise-aligned vortex shedding structures emerge (Taira & Colonius Reference Taira and Colonius2009b; Chen, Bai & Wang Reference Chen, Bai and Wang2016; Zhang et al. Reference Zhang, Hayostek, Amitay, He, Theofilis and Taira2020b; Zhu et al. Reference Zhu, Wang, Xu, Qu and Long2023). For swept wings, there is a spanwise shift of the reversed-flow and shedding structures. This shift results from sweep-induced spanwise flow emerging over the wing and stabilizing wake oscillations (Burtsev et al. Reference Burtsev, He, Hayostek, Zhang, Theofilis, Taira and Amitay2022; Ribeiro et al. Reference Ribeiro, Yeh, Zhang and Taira2022). Over swept wings, the reversed-flow bubble spreads over a substantial portion of the wingspan, especially near the wing tip (Zhang et al. Reference Zhang, Hayostek, Amitay, Burstev, Theofilis and Taira2020a; Zhang & Taira Reference Zhang and Taira2022). This large bubble formation makes it challenging to find an optimal location to perturb the reversed flow (McFadden, Brandt & Bons Reference McFadden, Brandt and Bons2022; Brandt, McFadden & Bons Reference Brandt, McFadden and Bons2023).
Despite differences in the wakes around unswept and swept wings at high incidence, they tend to exhibit similar lift-to-drag ratios. A higher lift and lift-to-drag ratio for laminar post-stall flow conditions is achieved for tapered wings with high backward-swept leading edges (Ribeiro et al. Reference Ribeiro, Neal, Burtsev, Amitay, Theofilis and Taira2023a). Wake patterns become increasingly complex around tapered wings, with vortex shedding spreading over a larger portion of the wingspan, while the wing tip vortex is considerably weakened compared with the tip vortex around an untapered wing.
The tip vortex, a quasi-steady streamwise vortical structure emerging due to pressure differences between the upper and lower sides of the wing, is particularly interesting for laminar post-stall flows around untapered unswept wings (Zhang et al. Reference Zhang, Hayostek, Amitay, He, Theofilis and Taira2020b). It can negatively affect the aerodynamics of wings, inducing drag, decreasing lift and reducing the effective angle of attack near the tip (Devenport et al. Reference Devenport, Rife, Liapis and Follin1996; Torres & Mueller Reference Torres and Mueller2004; Dong, Choi & Mao Reference Dong, Choi and Mao2020; Toppings & Yarusevych Reference Toppings and Yarusevych2021). The emergence of the tip vortex and its interaction with the inboard wake vortices affects the aerodynamic loads over the wing and results in a complex 3-D wake (Freymuth, Finaish & Bank Reference Freymuth, Finaish and Bank1987; Viieru et al. Reference Viieru, Albertani, Shyy and Ifju2005; Visbal Reference Visbal2012; Yilmaz & Rockwell Reference Yilmaz and Rockwell2012; Visbal, Yilmaz & Rockwell Reference Visbal, Yilmaz and Rockwell2013; Neal & Amitay Reference Neal and Amitay2023; Zhu, Wang & Liu Reference Zhu, Wang and Liu2024). Additionally, its persistence can substantially impact air mobility and traffic control (Spalart Reference Spalart1998).
The tip vortex is a common structure that appears over a broad range of Reynolds numbers. Control strategies that suppress its formation in the laminar regime provide insights for controlling tip vortices in turbulent flow conditions, which generally retain a laminar core. This is often observed for many other large-scale vortices emerging in post-stall wakes. Core wake structures in separated wakes exhibit topological similarities and find analogous vortical formations over a broad range of Reynolds numbers (Hunt et al. Reference Hunt, Abel, Peterka and Woo1978; Dallmann Reference Dallmann1988; Délery Reference Délery2001; Ribeiro, Frank & Franck Reference Ribeiro, Frank and Franck2020a). This suggests that flow control findings for post-stall flows in the low-Reynolds-number regime can be valuable for higher-Reynolds-number flows. For the case of the tip vortex, its control and attenuation have benefited from the study of flow perturbations and instabilities (Mayer & Powell Reference Mayer and Powell1992; Edstrand et al. Reference Edstrand, Schmid, Taira and Cattafesta III2018a,Reference Edstrand, Sun, Schmid, Taira and Cattafestab).
Due to the heterogeneity of the 3-D wake structures (Zhang et al. Reference Zhang, Hayostek, Amitay, Burstev, Theofilis and Taira2020a,Reference Zhang, Hayostek, Amitay, He, Theofilis and Tairab) and the non-trivial evolution of flow perturbations (Navrose, Brion & Jacquin Reference Navrose, Brion and Jacquin2019), the control of post-stall flows over wings may appear to be a daunting task. For such flows, an intuition-based control design may often lead to an ineffective flow modification and undesirable outcomes. To find strategies that efficiently modify the wakes, one may seek a proper spatial–temporal description of the actuation. This can be achieved studying the dynamics of optimal perturbations via triglobal resolvent analysis (Ribeiro et al. Reference Ribeiro, Yeh and Taira2023b; Ribeiro & Taira Reference Ribeiro and Taira2023).
Resolvent analysis, one of the many techniques extracting important features from fluid flows (Taira et al. Reference Taira, Brunton, Dawson, Rowley, Colonius, McKeon, Schmidt, Gordeyev, Theofilis and Ukeiley2017; Unnikrishnan Reference Unnikrishnan2023), is particularly attractive for flow control as it identifies optimal inputs that can be amplified into the flow field (Trefethen et al. Reference Trefethen, Trefethen, Reddy and Driscoll1993; Jovanović & Bamieh Reference Jovanović and Bamieh2005; McKeon & Sharma Reference McKeon and Sharma2010). Additionally, resolvent analysis reveals the unsteady response characteristics describing how optimal perturbations can potentially modify the base flow (Luhar, Sharma & McKeon Reference Luhar, Sharma and McKeon2014). This method has been used to study a wide range of flow applications (Moarref et al. Reference Moarref, Sharma, Tropp and McKeon2013; Schmidt et al. Reference Schmidt, Towne, Rigas, Colonius and Brès2018; Ricciardi, Wolf & Taira Reference Ricciardi, Wolf and Taira2022; Houtman, Timme & Sharma Reference Houtman, Timme and Sharma2023) and supported flow control designs over two-dimensional (2-D) base flows (Yeh & Taira Reference Yeh and Taira2019; Jin, Illingworth & Sandberg Reference Jin, Illingworth and Sandberg2020; Liu et al. Reference Liu, Sun, Yeh, Ukeiley, Cattafesta and Taira2021; Lin, Tsai & Tsai Reference Lin, Tsai and Tsai2023; Gross, Marks & Sondergaard Reference Gross, Marks and Sondergaard2024).
Leveraging insights from the aforementioned studies, this work considers flow control over low-aspect-ratio wings with two primary objectives: (i) reducing the volume of the separation bubble to enhance time-averaged lift and lift-to-drag ratio, and (ii) attenuating the wing tip vortex. To achieve these goals, we employ a direct wake modification approach (Choi, Jeon & Kim Reference Choi, Jeon and Kim2008) based on resolvent analysis, by introducing triglobal forcing modes as harmonic body forces. Our intent is not to suppress the separation bubble and vortex shedding. Instead, our aim is to strategically modify the 3-D wake dynamics to exploit vortices for aerodynamic enhancements.
The overview of the present work is illustrated in figure 1, where direct numerical simulation (DNS) flow structures are depicted using isosurfaces of the second invariant of the velocity gradient tensor, denoted as $Q$ (Hunt, Wray & Moin Reference Hunt, Wray and Moin1988; Jeong & Hussain Reference Jeong and Hussain1995), coloured by the spanwise vorticity $\omega _z$, while forcing and response modes are depicted by the isosurfaces of the velocity component $u_y$. Our study is comprised of three parts: (i) obtain baseline flows (without control), (ii) obtain resolvent modes that reveal the most sensitive regions to introduce harmonic perturbations to the flow and their nonlinear response characteristics, and (iii) introduce the input (forcing) modes as harmonic body forces to the flows and analyse the effectiveness of the control strategy. Our work is organized as follows. In § 2 we describe our problem set-up. In § 3 we present the numerical approach used in the present work; namely, DNS and triglobal resolvent analysis. In § 4 we present the time-averaged characteristics and the vortex dynamics of the baseline flows. In § 5 we present the insights obtained from resolvent analysis and how it supports flow control. In § 6 we describe our active flow control approach and show its application to tapered swept wings and the effects of control. Our conclusions are presented in § 7.
2. Problem set-up
We consider laminar flows over tapered swept wings with a NACA 0015 cross-sectional profile. For the Cartesian coordinate system, $(x,y,z)$ denote the streamwise, transverse and spanwise directions, respectively. The origin is placed at the leading edge with the NACA 0015 profile prescribed along the $(x,y)$ plane. The angle of attack is defined between the airfoil chord line and the streamwise direction and set to $\alpha = 14^\circ$ and $22^\circ$ for this study. Our set-up is detailed in figure 2. All wings considered herein present wing geometries with a sharp trailing edge and a straight-cut wing tip.
The 3-D wing is built by extrusion from the wing root in the spanwise direction over a half-span length of $b$. Along with the mean-chord length $c$, the semi aspect ratio of the wings is fixed as $sAR = b/c = 2$. Tapered wings consider a taper ratio defined by $\lambda = c_{tip} / c_{root}$, where $c_{tip}$ and $c_{root}$ are tip and root chord lengths, respectively. We consider tapered wings with $\lambda = 0.27$ and $1$, where $\lambda = 1$ is the untapered wing. For swept wings, the 3-D computational set-up is sheared in the chordwise direction and $\varLambda$ is the sweep angle defined between the $z$ direction and the leading edge axis. We consider sweep angles $\varLambda = 0^\circ$ and $30^\circ$.
For all flows studied herein, the mean-chord-based Reynolds number is defined as $Re_c \equiv U_\infty c /\nu = 600$, where $U_\infty$ is the free-stream velocity, $c$ is the mean-chord length and $\nu$ is the kinematic viscosity. Non-dimensionalization is carried as follows: spatial variables are normalized by the mean-chord length $c$, velocities are normalized by the free-stream velocity $U_\infty$ and time is reported in terms of convective time normalized by $c/U_\infty$.
3. Methodology
3.1. Direct numerical simulations
We study 3-D flows over wings by numerically solving the incompressible Navier–Stokes equations
where $\boldsymbol {u} = (u_x,u_y,u_z)$ is the velocity vector, $p$ is the pressure and $\boldsymbol {e}$ is external forcing. The latter term is modelled as a harmonic body force using the spatial–temporal characteristics of the triglobal forcing modes obtained from resolvent analysis (§ 3.2). The set of equations (3.1) is solved using Cliff, the incompressible flow solver from the CharLES package, developed by the Cascade Technologies, Inc. This solver uses collocated node-based second-order-accurate finite volume formulation to spatially discretize mass and momentum equations and a fractional step scheme for time integration (Ham & Iaccarino Reference Ham and Iaccarino2004; Ham, Mattsson & Iaccarino Reference Ham, Mattsson and Iaccarino2006).
With the origin of the Cartesian coordinate system placed at the leading edge of the wing root $(x,y,z)/c = (0,0,0)$, the computational domain extends over approximately $(x,y,z)/c \in [-20,25] \times [-20,20] \times [0,20]$. The present computational grids were also used in Ribeiro et al. (Reference Ribeiro, Neal, Burtsev, Amitay, Theofilis and Taira2023a). A symmetry boundary condition is imposed at the root. At the inlet, we prescribe a free-stream velocity vector $\boldsymbol {u} = (U_\infty,0,0)$. At the outlet, we specify the convective boundary condition. A slip boundary condition is set on all other far-field boundaries. Lastly, a no-slip wall boundary condition is enforced on the wing surface.
We perform DNS for baseline ($\boldsymbol {e} = 0$ in (3.1a)) and controlled flows ($\boldsymbol {e}$ modelled with harmonic forcing modes). For both cases, simulations are initiated from uniform flow with no external forcing, being performed with a constant Courant–Friedrichs–Lewy (CFL) number of 1 until transients are washed out of the computational domain, which takes approximately $t = 90$. After the transient flow features are washed out of the domain, flows are simulated with and without external forcing using a constant time step defined such that the CFL number is smaller than one. Statistics are collected for approximately $t = 100$ to ensure statistical convergence.
3.2. Resolvent analysis
Resolvent analysis can provide valuable insights for the design of active flow control strategies. Let us consider the Reynolds decomposition of state variable $\boldsymbol {q} = \bar {\boldsymbol {q}} + \boldsymbol {q}^\prime$, where $\bar {\boldsymbol {q}}$ is the time-averaged flow and $\boldsymbol {q}'$ is the statistically stationary fluctuation component. In this study, the base flows $\bar {\boldsymbol {q}}$ used for resolvent analysis are derived from compressible flow simulations with a free-stream Mach number $M_\infty \equiv U_\infty / a_\infty = 0.1$, where $a_\infty$ represents the free-stream speed of sound. The spatial distribution of the velocity components for both incompressible and compressible time-averaged flows exhibits similar patterns, as depicted in figure 3. For compressible flows, the major variations in thermodynamic quantities occur closer to the wing surface and remain within a $1\,\%$ difference from the free-stream values. Resolvent modes can be derived from both compressible and incompressible base flows. In the present work, a compressible resolvent approach is employed to build on our previous studies (Ribeiro et al. Reference Ribeiro, Yeh and Taira2023b; Ribeiro & Taira Reference Ribeiro and Taira2023).
With the compressible base flow, the aforementioned Reynolds decomposition is used to linearize the compressible Navier–Stokes equations about $\bar {\boldsymbol {q}}$ to yield
where $\boldsymbol{\mathsf{L}}_{\bar {\boldsymbol {q}}}$ is the discrete form of the linearized Navier–Stokes operator and $\boldsymbol {f}^\prime$ encompasses the nonlinear and external forcing terms (McKeon & Sharma Reference McKeon and Sharma2010). By considering the Fourier representation for $\boldsymbol {q}^\prime$ and $\boldsymbol {f}^\prime$, we have
which transforms (3.2) to read
where $\boldsymbol {x} = (x,y,z)$ and the triglobal response and forcing modes are $\hat {\boldsymbol {q}}_{\omega }$ and $\hat {\boldsymbol {f}}_{\omega }$, respectively, for a temporal frequency $\omega$. This expression leads to
with the resolvent operator $\boldsymbol{\mathsf{H}}_{\bar {\boldsymbol {q}},\omega } \in \mathbb {C}^{m \times m}$. The operator size $m$ is defined by the product of the number of state variables and the number of spatial grid points. Herein, the linear operators have size $m$ of approximately $5 \times 10^6$. We analyse the resolvent operator through the singular value decomposition
where $\boldsymbol{\mathsf{F}} = [\hat {\boldsymbol {f}}_1,\hat {\boldsymbol {f}}_2,\ldots,\hat {\boldsymbol {f}}_m]$ is an orthonormal matrix comprised of forcing modes, the diagonal matrix $\boldsymbol {\varSigma }=\text { diag}[\sigma _1,\sigma _2,\ldots,\sigma _m]$ holds the singular values (gain) in descending order and $\boldsymbol{\mathsf{Q}} = [\hat {\boldsymbol {q}}_1,\hat {\boldsymbol {q}}_2,\ldots,\hat {\boldsymbol {q}}_m]$ is an orthonormal matrix comprised of response modes (Trefethen et al. Reference Trefethen, Trefethen, Reddy and Driscoll1993; Jovanović & Bamieh Reference Jovanović and Bamieh2005).
The $\boldsymbol{\mathsf{H}}_{\bar {\boldsymbol {q}},\omega }$ operators are discretized over 3-D structured grids with the leading edge at the root positioned at $(x,y,z)/c = (0,0,0)$, extending over $(x, y, z)/c \in [-10,15] \times [-10,10] \times [0,10]$. The computational grids used for resolvent analysis are smaller in size than those used for DNS, we perform linear interpolation of the flow field between DNS and resolvent grids. Homogeneous Neumann boundary conditions are prescribed for $T'$ and homogeneous Dirichlet boundary conditions are set for the fluctuating variables $\rho '$ and $u'$ along the far field, airfoil surface and outlet. Far from the airfoil and in conjunction with the boundary conditions, sponges are applied (Freund Reference Freund1997).
The resolvent modes are computed using the randomized resolvent analysis algorithm (Ribeiro, Yeh & Taira Reference Ribeiro, Yeh and Taira2020b) and the direct and adjoint linear systems were directly solved using the MUMPS (multifrontal massively parallel sparse direct solver) package (Amestoy et al. Reference Amestoy, Duff, L'Excellent and Koster2001). The adjoint-based sensitivity analysis was used to interpolate the resolvent norm over frequencies $\omega$ (Schmid & Brandt Reference Schmid and Brandt2014; Fosas de Pando & Schmid Reference Fosas de Pando and Schmid2017). The codes used to compute the resolvent modes are part of the linear analysis package made available by Skene, Ribeiro & Taira (Reference Skene, Ribeiro and Taira2022).
4. Baseline flows
4.1. Time-averaged characteristics
To achieve the control objectives in this study, we first comprehensively examine the wake patterns and dynamics of the baseline flows. Specifically, for the control goal of reducing the separation bubble size, focus is placed on investigating key features of the reversed-flow bubble 3-D topology through the time-averaged flow field. The reversed-flow bubble has a non-homogeneous spatial distribution, significantly influenced by both the wing planform geometry and the angle of attack, as illustrated in figure 4. For visualization, we present the full span wing mirrored with respect to the wing root. The time-averaged reversed flow is depicted with light blue and purple isosurfaces of $\overline {u_x} = 0$ and $-0.1$, respectively.
Additionally, we present the time-averaged aerodynamic forces, reported as non-dimensional drag and lift coefficients, ${C_D}$ and ${C_L}$, respectively, defined as
where $F_x$ and $F_y$ are the $x$ and $y$ force components, respectively. For low-Reynolds-number flows, the time-averaged lift-to-drag ratio ($\overline {C_L/C_D}$), used throughout this work to quantify the aerodynamic performance of the wing, typically remains around $O(1)$ and reaches its peak at high angles of attack (Taira & Colonius Reference Taira and Colonius2009b; Zhang et al. Reference Zhang, Hayostek, Amitay, He, Theofilis and Taira2020b). Lift increases within the depicted $\alpha$ range, as seen in the $\overline {C_L}$ values in figure 4(a–c) for $\alpha = 14^\circ$ and figure 4(d–f) for $\alpha = 22^\circ$. Notwithstanding, the lift-to-drag ratio decreases with $\alpha$, indicating loss of aerodynamic performance as the angle of attack increases. This decline in aerodynamic efficiency at $\alpha = 22^\circ$, compared with $\alpha = 14^\circ$, is linked to a post-stall flow condition. Consequently, a flow control implementation becomes essential to assist the wing in maintaining aerodynamic efficiency.
Wing sweep and taper also influence aerodynamic loads. Overall, wing sweep is associated with a reduction in lift for untapered wings (Zhang et al. Reference Zhang, Hayostek, Amitay, Burstev, Theofilis and Taira2020a). The combination of a high leading edge sweep and wing taper proves advantageous for the aerodynamic performance of the wing, especially for post-stall flows (Ribeiro et al. Reference Ribeiro, Neal, Burtsev, Amitay, Theofilis and Taira2023a). Achieving a high lift-to-drag ratio is possible for steady wakes at lower angles of attack. However, for enhanced aerodynamic performance, the role of flow unsteadiness must be considered (Zhang et al. Reference Zhang, Hayostek, Amitay, He, Theofilis and Taira2020b). To take advantage of the inherent unsteadiness, we consider resolvent-analysis-based actuation that can excite unsteady structures in the wake. For realizing effective flow modification, we first investigate the characteristics of the reversed-flow bubble around the wings shown in figure 4.
For laminar flows over wings at high incidence angles, the separation bubble becomes massive, beyond the size of the wing. As shown in figure 4, the size of the reversed-flow bubble is more pronounced for flows over wings at $\alpha = 22^\circ$ and the intensity of the reversed flow within the separation bubble increases with the angle of attack, as evident from the larger $\overline {u_x} = -0.1$ isosurfaces. Additionally, the non-homogeneity of the reversed flow is observed in the spanwise direction, with the bubble expanding and contracting over the wingspan. For example, for untapered unswept wings $(\lambda,\varLambda = 1,0^\circ )$, the bubble shrinks near the wing tip while expanding in the inboard region.
The wingspan location where the separation bubble reaches its maximum sectional area in the $(x,y)$ plane is a key aspect of the reversed-flow topology. For control, this location is important as a direct wake modification implemented over this region can significantly reduce the reversed-flow volume. For untapered unswept wings at lower $\alpha$, the reversed-flow bubble is marked by the contraction of the reversed-flow region near the midspan, as depicted in figure 4(a). Zhu et al. (Reference Zhu, Wang, Xu, Qu and Long2023) noted that similar reversed-flow bubble shapes resemble the tail of a swallow and termed this reversed-flow topology as a swallow-tailed structure. With an increase in the angle of attack, they noted that the bubble transforms into a single-tailed formation, where the tail refers to a portion of the reversed-flow bubble with larger extension downstream of the wing in the streamwise direction. A single-tailed reversed-flow structure is analogous to the structure presented in figure 4(d). Such wake formation is commonly observed for 3-D flows over untapered unswept low-aspect-ratio wings at high angles of attack (Chen et al. Reference Chen, Bai and Wang2016).
In contrast to the flows over untapered unswept wings, for swept wings $(\varLambda = 30^\circ )$, the flow is attached over the midspan. For untapered swept wings $(\lambda,\varLambda = 1,30^\circ )$, shown in figure 4(b,e), the larger portion of the reversed-flow bubble emerges over the outboard side of the wing, closer to the tip. The characteristics of the reversed-flow bubble are further influenced by wing taper, as shown in figure 4(c,f). For tapered swept wings $(\lambda,\varLambda = 0.27,30^\circ )$, the larger portion of the reversed-flow structure appears over the inboard section of the wing. To gain further insights into the wakes, we examine the vortex dynamics of the wakes in the following section.
4.2. Vortex dynamics
Let us continue to study the features of flows over low-aspect-ratio wings by examining their spectral characteristics and instantaneous wakes illustrated in figure 5. In figure 5(a,b) we present the power spectral density (PSD) of $C_L$, where frequencies are normalized as
which is a modified Fage–Johansen Strouhal number (Fage & Johansen Reference Fage and Johansen1927) with a $1/\cos \varLambda$ scaling to account for the sweep angle. The lift spectra reveal peaks associated with vortex shedding. At $\alpha = 14^\circ$, the shedding structures are predominantly two dimensional near the wing root, resulting in smoother lift PSD curves when compared with those obtained at $\alpha = 22^\circ$, where shedding vortices are three dimensional. Despite the differences in wake shedding, lift peaks are found between $0.13 \le St \le 0.16$ for all cases shown. Within this frequency range, untapered unswept wings $(\lambda,\varLambda = 1,0^\circ )$ peak around the lower frequencies $St \approx 0.14$ while tapered swept wings $(\lambda,\varLambda = 0.27,30^\circ )$ peak around the higher portion of the frequency range $St \approx 0.16$. In figure 5(c,f) we examine the time-varying flows over low-aspect-ratio untapered unswept wings $(\lambda,\varLambda = 1,0^\circ )$ at $\alpha = 14^\circ$ and $22^\circ$. Notably, the global unsteady characteristics of the flow share similarities for both angles of attack. Near the root, unsteadiness is predominantly marked by the emergence of vortices aligned in the spanwise direction. At the wing tip, a steady flow displays a tip vortex oriented along the streamwise direction. The streamwise length of this tip vortex is more pronounced for $\alpha = 22^\circ$.
Wing sweep plays a stabilizing role in attenuating wake oscillations around 3-D wings (Zhang et al. Reference Zhang, Hayostek, Amitay, Burstev, Theofilis and Taira2020a; Burtsev et al. Reference Burtsev, He, Hayostek, Zhang, Theofilis, Taira and Amitay2022), as shown in figure 5(d,g). At the lower $\alpha$, unsteadiness is entirely suppressed. However, at $\alpha =22^\circ$, the flow exhibits unsteadiness near the wing tip, while remaining steady near the wing root. For the higher $\alpha$, the unsteady flow structures develop farther away from the wing.
Figure 5(e,h) reveals that the wake patterns of tapered swept wings $(\lambda,\varLambda = 0.27,30^\circ )$ exhibit notable similarities with those around untapered unswept wings $(\lambda,\varLambda = 1,0^\circ )$. However, a distinctive feature is the significant shortening of the tip vortex in tapered swept wings. Despite the pronounced leading edge sweep angle, the wakes of tapered swept wings are unsteady. Vortex shedding structures feature spanwise rolls, akin to the flows around untapered unswept wings shown in figure 5(c,f). The shift in flow unsteadiness along the spanwise direction, particularly toward the quarter-span (located halfway between the wing root and tip), coincides with the larger expansion of the reversed-flow bubble size over the wingspan, as depicted in figure 4(e,h).
5. Triglobal resolvent analysis
Resolvent analysis reveals the spatial regions with high receptivity to external perturbations, the optimal frequency of actuation and the harmonic response of the flow field. These insights can support flow control design by uncovering the responsiveness of the flow field to optimal perturbations. We discuss how the findings obtained from resolvent analysis can support flow control using the resolvent modes over wings at $\alpha = 22^\circ$, as shown in figure 6. We present the leading resolvent gain spectra and the forcing-response mode pairs at $St = 0.14$. As seen in figure 6(a), the frequency peaks for the highest gain $\sigma _1$ at $St \approx 0.14$ are consistent across various wing planforms. Another commonality in the resolvent modes is attributed to the convective nature of the resolvent operator, where forcing modes manifest upstream of the wing, while response modes emerge downstream in the wake.
Resolvent modal structures exhibit a pattern of spatial oscillations in the streamwise direction, whose wavelength scale relates to the modal frequency and the convective physics of the base flow. For this reason, lower-frequency resolvent modes usually have larger streamwise wavelengths, while higher-frequency resolvent modes exhibit shorter streamwise wavelengths. It is important to note that resolvent modes are defined over the entire domain, albeit being in a non-uniform manner. That is, resolvent mode have a localized larger amplitude over certain regions, i.e. regions with higher spatial support of forcing or response modes. For the flow fields considered herein, the higher spanwise support of each pair of forcing and response modes appears over the same portion of the wingspan. As the frequency increases, there is a shift in the spatial support of forcing-mode pairs across the wingspan.
We illustrate the connection between the spatial support of forcing-response mode pairs over the wingspan $(z/c)$ and their frequency $(St)$ in figure 6(b–d) using the contours of
where $\|\hat {\boldsymbol {f}}\|_2$ and $\|\hat {\boldsymbol {q}}\|_2$ are the $2$-norm of $\hat {\boldsymbol {f}}$ and $\hat {\boldsymbol {q}}$, respectively, at each grid point of the computational domain. These modes are defined by five state variables, denoted as $\hat {\boldsymbol {f}} = [\hat {\boldsymbol {f}}_\rho,\hat {\boldsymbol {f}}_{ux},\hat {\boldsymbol {f}}_{uy}, \hat {\boldsymbol {f}}_{uz},\hat {\boldsymbol {f}}_T]$ and $\hat {\boldsymbol {q}} = [\hat {\boldsymbol {q}}_\rho,\hat {\boldsymbol {q}}_{u_x},\hat {\boldsymbol {q}}_{u_y},\hat {\boldsymbol {q}}_{u_z},\hat {\boldsymbol {q}}_T]$, under the Chu norm (Chu Reference Chu1965). As $\|\hat {\boldsymbol {f}}\|_2$ and $\|\hat {\boldsymbol {q}}\|_2$ are integrated over spanwise slices of the domain, $S(x,y)$, the $\varOmega _{\hat {\boldsymbol {f}}}$ and $\varOmega _{\hat {\boldsymbol {q}}}$ shows the wingspan region over which the forcing-response mode pair has higher spatial support. For the visualization in figure 6(b–d), $\varOmega _{\hat {\boldsymbol {f}}}$ and $\varOmega _{\hat {\boldsymbol {q}}}$ are normalized based on their respective maximum values at each $St$. These contours are then represented using red and blue shades, where $\varOmega _{\hat {\boldsymbol {f}}}/\| \varOmega _{\hat {\boldsymbol {f}}} \|_\infty \ge 0.5$ and $\varOmega _{\hat {\boldsymbol {q}}}/\| \varOmega _{\hat {\boldsymbol {q}}} \|_\infty \ge 0.5$, respectively. This approach results in a heatmap illustrating the spatial distribution of $\hat {\boldsymbol {f}}$ and $\hat {\boldsymbol {q}}$ across the wingspan for each frequency.
The spatial support over the wingspan for the forcing-response mode pairs at the frequency corresponding to the resolvent gain peak coincides with the spanwise location where the reversed-flow bubble is larger. Specifically, for the untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$ at $\alpha = 22^\circ$, the dominant mode pair at $St = 0.14$ displays root-dominant modal structures seen in figure 6(b) analogous to the shape of the shedding vortices observed in the DNS. However, with increasing frequency, the spatial support of the forcing-response mode pairs gradually transitions in the spanwise direction from the root region towards the wing tip. Resolvent analysis indicates that lower-frequency actuation ($St \le 0.20$) is more responsive and prone to altering wake dynamics when applied near the wing root. Conversely, actuation at $St > 0.20$ demonstrates greater potential for modifying the wake closer to the wing tip.
With the insights from the resolvent modes, we can strategically determine the region within the flow field that amplifies unsteadiness to attain a specific control objective. For the untapered swept wing illustrated in figure 6(c), the larger portion of the reversed-flow bubble appears at the wing tip. Consequently, the forcing-response mode pairs at the peak resolvent gain frequency, $St = 0.14$, emerge closer to the wing tip region. As frequencies increase, spatial support shifts from the wing tip towards the wing root for $St > 0.20$.
For the flow over the tapered swept wing $(\lambda,\varLambda = 0.27,30^\circ )$ depicted in figure 6(d), the reversed-flow bubble is prominent over the quarter-span. Therefore, the forcing-response mode pairs at the resolvent gain frequency peak also emerge near the quarter-span. There is a distinct shift of spatial support towards the wing root for $0.20 \le St < 0.30$, and at higher frequencies ($St \ge 0.30$), the modes shift towards the wing tip. For the sake of brevity, we do not discuss the suboptimal resolvent modes, since we are interested in flow control techniques based on the primary modes. Discussion on the subdominant modes can be found in Ribeiro et al. (Reference Ribeiro, Yeh and Taira2023b) and Ribeiro & Taira (Reference Ribeiro and Taira2023).
6. Controlled flows
6.1. Implementation of resolvent-analysis-based actuation
Resolvent analysis finds the optimal perturbation that can be amplified in the flow field. However, the receptivity of low-Reynolds-number separated 3-D flows to external perturbations remains elusive. To address this issue, forcing modes obtained from resolvent analysis are introduced as a harmonic external body force $\boldsymbol {e}$ in (3.1a). The body force is used in the numerical simulation to model actuators employed in practical flow control applications. For instance, the control effects of dielectric barrier discharge plasma actuators have been studied numerically using body forces (Shyy, Jayaraman & Andersson Reference Shyy, Jayaraman and Andersson2002; Mullenix, Gaitonde & Visbal Reference Mullenix, Gaitonde and Visbal2013; Waindim & Gaitonde Reference Waindim and Gaitonde2016) and surface heat actuators (Yeh, Munday & Taira Reference Yeh, Munday and Taira2017; Prasad & Unnikrishnan Reference Prasad and Unnikrishnan2023). For this reason, even though this study is a fundamental analysis of the 3-D post-stall flow control, the spatio-temporal characteristics of the body forces presented here can be approximated in practical flow control applications.
The spatial distribution of the forcing modes and their frequency $\omega$ is used within the definition of the body force $\boldsymbol {e}$ expressed as
where $\hat {\boldsymbol {f}}(\boldsymbol {x})$ is the spatial forcing mode, with real $\text {Re}({\cdot })$ and imaginary $\text {Im}({\cdot })$ parts, $A$ is the amplitude and $\phi$ is the phase. For all controlled flows considered herein, $\phi$ is set to initiate the body force actuation at the time of maximum $C_L$. The resolvent modes $\hat {\boldsymbol {f}}$ and $\hat {\boldsymbol {q}}$ are weakly compressible, being derived from a base flow characterized by a free-stream Mach number of $M_\infty = 0.1$ (Ribeiro & Taira Reference Ribeiro and Taira2023). Only velocity components of $\hat {\boldsymbol {f}}$ are used in (6.1).
Forcing modes are spatially global, extending over the entire computational domain $(\boldsymbol {x})$, with higher spatial support upstream of the wing, as depicted in figure 7(a). To provide fundamental insights into separation control, we narrow our focus to actuation over a specific subset of $\boldsymbol {x}$. We term this approach as spatially confined actuation, in which body forces are introduced within a volume of actuation ($V_{act}$) and its corresponding actuation surface ($S_{act}$), defined as the outer surface of the actuation volume. Our procedure to define $V_{act}$ will be discussed in the following section. It is noteworthy that global and localized actuation lead to distinct control outcomes, as depicted in figure 7(b,c).
This study adopts a confined actuation approach for two primary reasons. First, global forcing modes emerge upstream far from the wing, making them unrealistic for practical aircraft actuation and flow control. Secondly, confined actuation enables us to discern the effects of control over specific regions of the wingspan. The spanwise support of forcing modes changes as the frequency of actuation varies (§ 5). Let us take the example of a global forcing actuation using forcing modes at $St = 0.14$ and $0.26$ using the same body force amplitude $A$. Notably, the forcing modes at $St = 0.14$ have stronger spatial support over the wing root, while those at $St = 0.26$ are more pronounced at the wing tip. Nevertheless, global actuation yields similar lift over time for both frequencies, as seen in figure 7(b). Additionally, global actuation with the $St = 0.14$ forcing mode alters the wake across the entire wingspan, perturbing the tip vortex upstream in the wake, as observed in figure 7(c). In contrast, the control effects of the confined actuation in the wake are concentrated in the root region.
6.2. Volume of actuation and momentum coefficient
The objective of control is to achieve notable flow modifications using a small forcing input. To quantify the magnitude of the control input, we consider the momentum coefficient $C_\mu$ defined as
where ${u_x^\prime }$, ${u_y^\prime }$ and ${u_z^\prime }$ are the velocity components induced by the actuation body force $\boldsymbol {e}$ defined in $V_{act}$. The induced velocity is measured in a calibration simulation in which the free-stream flow is turned off. The determination of an actuation volume involves the analysis of the magnitude of $\hat {\boldsymbol {f}}$:
This scalar variable is defined across the spatial domain for each forcing mode and serves as a velocity-based metric depicting the spatial support of the forcing modes.
The actuation volume, denoted as $V_{act}$, is specified within the region where
This threshold is selected for two main reasons: (i) $V_{act}$ is limited to a region closer to the wing surface for all cases studied herein, and (ii) the region of spanwise support for the forcing modes can be clearly distinguished for modes at different frequencies (see figure 6). A yellow isosurface illustrates the definition of $V_{act}$, as seen in figure 8, along with red and blue isosurfaces representing the global modes with $\hat {\boldsymbol {f}}_{ux} / \| \hat {\boldsymbol {f}}_{ux} \|_\infty = \pm 0.1$.
Following the definition of $V_{act}$, simulations are conducted under quiescent free-stream flow with actuation to estimate the momentum coefficient $C_\mu$. The velocity components of the forcing mode, denoted as $\hat {\boldsymbol {f}} = [\hat {\boldsymbol {f}}_{ux},\hat {\boldsymbol {f}}_{uy},\hat {\boldsymbol {f}}_{uz}]$, each having unit magnitude ($\| \hat {\boldsymbol {f}} \|_2 = 1$), are introduced to the momentum equation (3.1a), as illustrated in figure 8(b), with $Q = 0.1$. To enlarge the flow structures for visualization purposes, the chosen value of $Q$ in this context is $10$ times lower than that used throughout the paper. As shown in figure 8(c), lift fluctuation induced by actuation under quiescent free-stream flow conditions remains under approximately $1\,\%$ of the baseline $C_L$ for $C_\mu \le 0.05$. Through simulations of quiescent free-stream flows, we obtain $u_x^\prime$, $u_y^\prime$ and $u_z^\prime$ for (6.2) to be evaluated over $V_{act}$, revealing a linear relation between $C_\mu$ and the actuation amplitude $A$, as illustrated in figure 8(d). For $C_\mu = 0.05$, the value of $A$ is of order $O(1)$, exhibiting a magnitude similar to previous studies implementing body force actuation in comparable flow conditions (Edstrand et al. Reference Edstrand, Sun, Schmid, Taira and Cattafesta2018b).
In our analysis we maintain a constant $C_\mu = 0.05$. It is noteworthy that variations in $C_\mu$ may induce changes in the controlled wake, as illustrated in figure 9. This figure depicts the impact of different $C_\mu$ values on flow control over an untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$ at $\alpha = 22^\circ$. Focusing on the controlled flows with a forcing mode at $St = 0.40$, situated near the wing tip, the effect of $C_\mu$ on the controlled tip vortex length is relatively minor, as demonstrated in figure 9(a). Notably, an approximately $60\,\%$ reduction in the tip vortex length is achieved for all considered $C_\mu$ values.
When examining controlled flows with a $St = 0.14$ forcing mode located inboard over the wing, an increase in $C_\mu$ results in higher time-averaged and root-mean-squared (RMS) values for $C_L$ and $C_L/C_D$, as presented in figure 9(b). We note that a smaller $C_\mu$ could be used to reduce RMS levels and its impact on structural vibration of the wing. Given our objective to reduce the separation bubble size and enhance time-averaged lift and the lift-to-drag ratio, we specifically select $C_\mu = 0.05$ as it yields superior improvements in aerodynamic performance. Importantly, even at lower $C_\mu$ values, there is a notable increase in both $\overline {C_L}$ and $\overline {C_L/C_D}$, such as a $4.73\,\%$ increase in $\overline {C_L}$ for $C_\mu = 0.05$ compared with $C_\mu = 0.01$. Similarly, $C_{L_{RMS}}$ is $0.067$ for $C\mu = 0.01$, while it increases to $0.103$ for $C_\mu = 0.05$.
6.3. A priori assessment and guidance for flow control
With the forcing-mode-based actuation established, let us consider an a priori assessment of the control design and its impact on the wake. To this end, we quantify mixing introduced by the modal structures using the modal streamwise, transverse and spanwise Reynolds stresses (Luhar et al. Reference Luhar, Sharma and McKeon2014; Yeh & Taira Reference Yeh and Taira2019) respectively defined as
where $\text {Re}({\cdot })$ denotes the real part of the complex-valued variable. To assess the modal capability to perturb a flow structure, we employ the following mixing metric as
where $V_{resp}$ denotes a specific region in space of the response modes over which the integral is computed. This region is chosen based on the flow structure targeted for modification through flow control.
For reducing the size of the reversed-flow bubble, let us define $V_{resp}$ where $\overline {u_x} \le 0$, as shown by the blue isosurfaces over both wings in figure 10. For the untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$, note that the peak of the blue curve in figure 10(a) suggests that the forcing modes at $St \approx 0.14$ have higher potential to induce momentum mixing within the separation bubble, consequently achieving the control objective of reducing the reversed-flow bubble size. Conversely, when analysing $M$ over the wing tip vortex, we define $V_{resp}$ to be the region for $\overline {\omega _x} \le -0.5$ and $z/c \ge 1.65$, as shown in figure 10(a). In this case, the control objective shifts to perturbing and mitigating the tip vortex (represented in red). The red curve peaks around $St \approx 0.26$, suggesting that forcing modes at this frequency can augment momentum mixing within the tip vortex, potentially weakening its core and reducing its length.
Turning our attention to figure 10(b), we focus on the untapered swept wing $(\lambda,\varLambda = 1,30^\circ )$ scenario. Here, the peak of $M$ for the blue curve suggests that a $St \approx 0.10$ forcing mode is likely to yield a larger contraction of the reversed-flow bubble. For the untapered swept wing, utilizing the tip-dominant $St = 0.10$ forcing mode substantially modifies the flow around the tip. Nevertheless, this actuation may not impact the entire reversed-flow bubble, as the upstream portion of the separated flow is located near the wing root. To address this issue, we pursue higher-frequency forcing modes that emerge near the wing root. To identify the forcing modes that enhance momentum mixing and modify the reversed-flow bubble near the wing root (highlighted in yellow), we define $V_{resp}$ as the region where $|\overline {\omega _z}| \ge 5$ and $z/c \le 0.5$. This span subset confines the analysis to the root region while also encompassing the upstream portion of the reversed-flow bubble. The $|\overline {\omega _z}|$ threshold only affects the magnitude of $M$ and not its distribution over $St$. We note that earlier discussions about an untapered unswept wing have excluded the wing-root-based analysis because it closely aligns with the blue curve for the reversed-flow-based analysis shown in figure 10(a).
For the untapered swept wing, the distribution of the wing-root-based $M$ suggests the utilization of a root-dominant $St = 0.18$ forcing mode for actuation. For frequencies $St \ge 0.20$, both wing-root-based and reversed-flow-based $M$ decrease. A rapid decline in the reversed-flow-based $M$ implies that the actuation with $St \ge 0.20$ forcing modes increases momentum mixing near the root while minimally affecting the reversed-flow bubble. Distinguishing the effects of reversed-flow- and wing-root-based metrics is challenging for tapered swept wings $(\lambda,\varLambda = 0.27,30^\circ )$ because the separation bubble over this wing is centred at quarter-span, as depicted in figure 10(c). For a tapered swept wing at $\alpha = 22^\circ$, the reversed-flow-based $M$ peaks at $St = 0.14$, suggesting this mode for an actuation to reduce the reversed-flow bubble size. The wing-root-based metric exhibits two peaks: the first at $St = 0.14$ as the wing-root-based $V_{resp}$ encompasses part of the reversed-flow bubble. The second peak of the wing-root-based $M$ appears at $St = 0.20$ for a root-based actuation, while the reversed-flow-based metric $M$ remains high. This result suggests that actuation using $St = 0.20$ forcing mode can yield significant effects over the reversed-flow region.
It is important to note that analysing $M$ alone does not guarantee improvements in lift and lift-to-drag ratio for the controlled flows. Such enhancements need to be confirmed through experiments and numerical simulations, as demonstrated in the subsequent sections. Furthermore, we show how the behaviour of controlled flows concurs with predictions made by the Reynolds stresses using the response modes. For the remainder of this paper, we narrow our discussion to the three cases depicted in figure 10, as they present distinct and challenging flow features for control, including a variety of separation bubble spatial characteristics and the emergence of wing tip vortices.
6.4. Control of flow separation around untapered unswept wings
Let us study the wake modification achieved by the present resolvent-analysis-based active flow control approach for an untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$ at $\alpha = 14^\circ$. For reference, the baseline flow is visualized using grey-coloured isosurfaces of $Q$, as shown in figure 11(a). Also shown over the wing is a blue isosurface representing the reversed-flow bubble, where $\overline {u_x} \le 0$. For this flow, we observe spanwise-aligned vortex shedding over the majority of the wing and a tip vortex near the free end.
The DNS of controlled flows shows substantial differences compared with baseline flows. A quantitative assessment of the control effect is shown in figure 11(b). Here, the percentage difference ($\varDelta$) is used to illustrate variations in flow features between the baseline and controlled flows. In particular, let us analyse the blue curve that represents the contraction (negative) and expansion (positive) effect of flow control on the reversed-flow bubble, which is one of the objectives of the present study. The minimum reversed-flow bubble volume is achieved when the forcing mode at $St = 0.14$ is used for actuation. At this frequency, the reversed-flow bubble undergoes a $50\,\%$ volume reduction, as seen in figure 11(d).
The notable reduction in the reversed-flow bubble size at $St = 0.14$ leverages the forcing-response mode pair at this frequency. In particular, the response mode emerges over the baseline separation bubble, indicating that the forcing-mode actuation excites structures within the reversed-flow bubble. Indeed, along the spanwise-aligned root vortices, the controlled flow using forcing modes at $St = 0.14$ induces spatial oscillations in the wake that are absent in the baseline flow, as seen in figure 11(d). These structures perturb the baseline reversed-flow bubble and result in its volumetric contraction.
Concurrently, the controlled flow with $St = 0.14$ forcing-mode actuation exhibits the highest increase in lift and lift-to-drag ratio, shown by the percentage difference in $\overline {C_L}$ and $\overline {C_L/C_D}$ between the baseline and controlled flows (grey curves). We note that improvements in the aerodynamic performance are achieved because the amount of lift increase is substantially greater than that of the drag. The concomitant $\overline {C_L/C_D}$ increase and reversed-flow bubble contraction shown in figure 11(b) indicate that diminishing the reversed-flow size enhances the overall aerodynamic performance of the wing. As the actuation frequency increases, the higher spatial support of the forcing-mode pairs shifts toward the wing tip and the modes emerge outside the reversed-flow region. As a result, the effect of contracting the reversed-flow bubble is minimized for high-frequency actuation, reaching a plateau for $St \ge 0.26$.
Forcing-mode actuation for $St \ge 0.26$ is also important for flows over untapered unswept wings $(\lambda,\varLambda = 1,0^\circ )$ due to their ability to control the tip vortex while moderately increasing lift and lift-to-drag ratio, as seen in figure 11(b). The attenuation and control of tip vortices has been extensively studied (Gursul et al. Reference Gursul, Vardaki, Margaris and Wang2007; Greenblatt Reference Greenblatt2012; Gursul & Wang Reference Gursul and Wang2018) due to its adverse effects on wing aerodynamics (Francis & Kennedy Reference Francis and Kennedy1979; Katz & Bueno Galdo Reference Katz and Bueno Galdo1989; Green & Acosta Reference Green and Acosta1991; Devenport et al. Reference Devenport, Rife, Liapis and Follin1996) and its negative impact in air transportation (Spalart Reference Spalart1998). In prior studies involving laminar steady flow around an untapered unswept wing, a $21\,\%$ reduction was achieved using instability analysis modes as body forces (Edstrand et al. Reference Edstrand, Schmid, Taira and Cattafesta III2018a,Reference Edstrand, Sun, Schmid, Taira and Cattafestab). For this approach, a vortex instability was taken advantage of to increase dissipation of the tip vortex.
While the $St = 0.14$ forcing mode proves highly effective in diminishing the volume of the separation bubble, its impact on the reduction of the tip vortex length is relatively modest, as seen in the red curve of figure 11(b). Here, the control effect on the tip vortex is measured through the percentage difference between the baseline and the controlled tip vortex lengths. For figure 11(b), the tip vortex length is estimated using the distance in the streamwise direction between the trailing edge and the tip of the $\overline {\omega _x} = -1$ isosurface. While the chosen value of the $\overline {\omega _x}$ isosurface is arbitrary, it does not affect the findings.
A decrease in the tip vortex length is achieved for the control using $St \le 0.10$ forcing modes, reaching a local minimum at $St = 0.06$. The forcing-response mode pair at $St = 0.06$ and the corresponding controlled flow are depicted in figure 11(c). This actuation induces prominent streamwise vortices over the inboard region, perturbing the reversed-flow bubble and diminishing its volume. These structures also interact with the downstream portion of the tip vortex, resulting in an overall reduction in its length.
To achieve a more substantial weakening of the tip vortex, forcing modes at higher frequencies are employed for direct wake modification. The controlled flows with $St \ge 0.26$ forcing modes achieve a higher level of reduction in the tip vortex length, while preserving the baseline reversed-flow bubble, as depicted in figure 11(e) for the controlled flow with the $St = 0.28$ forcing mode near the wing tip, structures excited by the forcing mode emerge predominantly from the pressure side of the wing tip and induce a helical vortical structure formation that is associated with a significant reduction of the tip vortex length. Moreover, the weakening of the tip vortex alleviates the inboard downwash, resulting in a $6\,\%$ overall lift increase.
Figure 12(a) shows the sectional lift ($C_l$) over the wingspan for baseline and controlled flows at different actuation frequencies. The $z/c$ region where $C_l$ increases, compared with the baseline flow, coincides with the spanwise region where the forcing-response mode pairs have higher spatial support. For instance, for the $St = 0.10$ forcing-mode actuation, the most pronounced increase in $C_l$ is observed between $0.5 \le z/c \le 1.2$, contributing to a $16\,\%$ overall lift increase. Similarly, for the controlled flow with $St = 0.14$ forcing mode, a larger rise in $C_l$ is evident over a broader portion of the wingspan between $0 \le z/c \le 1.5$, resulting in $31\,\%$ total lift increase. For the controlled flow with $St = 0.18$ forcing mode, the greatest increase in lift occurs over a narrower wingspan region compared with the control with $St = 0.14$. For the control with $St = 0.18$ forcing mode, lift increases especially closer to the wing tip between $0.7 \le z/c \le 1.7$, resulting in a $22\,\%$ increase in the overall lift.
The $C_l$ increase results from vortical lift from near-wake structures excited by the actuation. The signature of these vortical structures advecting over the wing marks the skin friction field over their suction side, as seen in figure 12(b), showing that separation is not suppressed. Using force element analysis (details in Appendix A), we reveal how such near-wake structures contribute to lift in figure 13. Drag elements distribution, qualitatively similar to lift elements, are not shown for brevity. Lift elements show that the major lift contribution (positive, red) comes from the flow structures located outside of the reversed-flow region over a significant portion of the wingspan.
For force element analysis, the volume force elements are identified by the dot product of the Lamb vector ($\boldsymbol {\omega } \times \boldsymbol {u}$) and the gradient of the auxiliary potential ($\boldsymbol {\nabla } \phi _i$). The auxiliary potential field decays rapidly in magnitude far from the wing surface. The $\boldsymbol {\nabla } \phi _i$ characteristics are only affected by the wing planform, being consistent for baseline and controlled flows. For this reason, a strategic wake modification that reduces the reversed-flow bubble size has the potential to bring vortices closer to the wing where $\boldsymbol {\nabla } \phi _i$ has a higher magnitude. Consequently, flow structures emerging in controlled flows near the wing have higher contribution to the overall vortical lift. It is important to note that the higher magnitude of $\boldsymbol {\nabla } \phi _i$ consistently appears near the wing surface for all wing planforms and local lift enhancements result from the strengthening of lift elements caused by the flow field. For instance, for flows over untapered and tapered swept wings, Zhang & Taira (Reference Zhang and Taira2022) and Ribeiro et al. (Reference Ribeiro, Neal, Burtsev, Amitay, Theofilis and Taira2023a) have shown that major increases in root contribution to the overall lift results from the emergence of root-based vortices.
As shown in figure 13(a,b) for the baseline and controlled flow with the $St = 0.14$ forcing mode, the reversed-flow bubble size significantly decreases at $z/c = 0.5$ and $0.8$. This causes lift elements to emerge nearer to the wing compared with the baseline. Consequently, the highest lift increase occurs near the inboard quarter-span of the wing, as depicted by the red curve in figure 12(a). For the controlled flow with $St = 0.18$, the reversed-flow bubble reduces significantly over the outboard portion of the wingspan at $z/c = 1.2$ when compared with the baseline case, as depicted in figure 13(a,c). This reversed-flow structure contraction at $z/c = 1.2$ causes lift elements to emerge over this region and closer to the wing. As a result, this flow modification leads to a substantial lift increase over the outboard quarter-span of the wing, as seen in the yellow curve in figure 12(a). The control effects resulting from actuation at the shedding frequency over an untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$ at $\alpha = 14^\circ$ are analogous to those observed at $\alpha = 22^\circ$ (discussions are omitted for brevity).
6.5. Control of flow separation around untapered swept wings
For separated flows over untapered swept wings $(\lambda,\varLambda = 1,30^\circ )$, our objective is to directly modify the wake and control the size of the reversed-flow bubble. Unlike the findings presented in § 6.4, achieving the maximum reduction in the volume of the reversed-flow bubble around swept wings may not necessarily lead to optimal lift and lift-to-drag ratio enhancements. To illustrate the control effects, let us examine the laminar separated flow around a swept wing with $\varLambda = 30^\circ$ at $\alpha = 14^\circ$. The steady baseline flow is depicted in the insert visualization of figure 14(a). The reversed-flow region is highlighted with a blue isosurface at $\overline {u_x} = 0$. The application of resolvent-analysis-based actuation results in unsteady wakes that modify the 3-D dynamics about the reversed-flow bubble, contracting its volume.
The baseline reversed-flow bubble is larger near the tip. Consequently, to achieve the most significant reduction in the reversed-flow bubble volume, direct wake modification is applied near the wing tip. In this regard, the flow field is actuated using a forcing mode in the frequency range of $0.10 \le St \le 0.14$, whose spatial support is predominantly concentrated near the wing tip. As shown in figure 14(b), the controlled flow at these frequencies induces a local shedding close to the tip, exciting structures that perturb and modify the reversed-flow bubble. Given the actuation near the wing tip, the inboard flow near the wing root remains undisturbed.
The reduction of the reversed-flow bubble size, through actuation with $0.10 \le St \le 0.14$ forcing mode, results in a significant improvement in lift and lift-to-drag ratio. The most pronounced aerodynamic enhancements in $\overline {C_L}$ and $\overline {C_L/C_D}$ are achieved when promoting structures near the wing root, where the baseline flow is attached to the wing surface. To actuate in this region, we employ the forcing mode at $St = 0.18$, which exhibits larger spatial support near the wing root, as depicted in figure 14(c). This actuation substantially increases the root contribution to the overall lift, as seen in figure 14(d). As discussed for controlled flows over the untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$ in § 6.4, the strengthening of near-surface vortices over a section of the wingspan yields sectional lift enhancements. The coherent structures promoted by the actuation mechanism produce the $C_l$ increase near the tip for the controlled flow with the tip-based forcing mode at $St = 0.10$. In contrast, the actuation with the root-based forcing mode at $St = 0.18$ produces a higher increase in $C_l$ near the root.
The lift and lift-to-drag ratio enhancements achieved through control using the $St = 0.18$ forcing mode surpass those obtained with other actuation frequencies. In fact, controlled flows with actuation frequencies $St \ge 0.20$ experience a significant decline in lift and lift-to-drag ratio improvements, despite utilizing a spatial support over the wing root similar to that of the $St=0.18$ forcing mode. Moreover, as depicted in the blue curve of figure 14(a), controlled flows using $St \ge 0.24$ forcing modes increase the size of the reversed-flow bubble. As illustrated in figure 15(a–c), which compares controlled flows using $St=0.12$, $0.18$ and $0.24$, only actuation using the $St = 0.18$ forcing mode induces a global wake modification that alters flow dynamics across the entire wingspan. Both lower- and higher-frequency forcing modes primarily alter flow in specific regions where actuation occurs, near the wing tip for $St=0.12$ and near the root for $St=0.24$. Controlled flows with the $St \ge 0.24$ forcing modes yield minor changes on the reversed flow because their spatial support is concentrated near the wing root region and do not merge into the separated flow bubble. The aerodynamic modifications achieved with $St \ge 0.24$ are not related to any changes in the reversed-flow bubble but are mainly due to the emergence of near-surface vortices excited by the actuation mechanism. As shown in figure 15(d), for the controlled flow with $St =0.18$, the global wake modification is initiated by the perturbation, arising near the wing root and rapidly evolving downstream into hairpin-like vortices that reshape the overall wake dynamics. Consequently, the controlled flow using the $St=0.18$ forcing mode benefits from a local lift increase around the root-based actuation and a subsequent reduction in the reversed-flow bubble, leading to significant aerodynamic improvements.
The periodic controlled flows synchronize with the actuation frequency, as shown by the PSD of $C_L$ in figure 14(e). Here, the lift spectra peaks at the input frequencies and its harmonics for both $St=0.10$ (blue) and $St = 0.18$ (yellow) controlled flows. The actuation frequency affects the size of flow structures, as the higher-frequency input yields elongated spanwise-aligned vortices, as shown by the probed $u_y$ along $(x,y)/c = (3,-0.5)$ over time in figure 14(f). Additionally, the higher-frequency actuation yields a lower lift-to-drag RMS. While $(C_L/C_D)_{RMS} = 0.148$ for the controlled flow at $St = 0.10$, the root-based controlled flow at $St = 0.18$ results in $(C_L/C_D)_{RMS} = 0.079$. For brevity, only the control effects for the untapered swept wing $(\lambda,\varLambda = 1,30^\circ )$ at $\alpha = 14^\circ$ are presented here. We note that the control effects are analogous for both angles of attack. At $\alpha = 22^\circ$, the control using a lower-frequency mode near the wing tip is also less effective in improving lift and aerodynamic performance than a higher-frequency forcing mode located near the wing root (see figure 1).
6.6. Control of flow separation around tapered swept wings
For post-stall flows over tapered swept wings, our aim is to control the size of the reversed-flow bubble. Flow control effects over tapered swept wings are consistent with those observed for untapered swept wings, as discussed in § 6.5. For a tapered swept wing $(\lambda,\varLambda = 0.27,30^\circ )$ at $\alpha = 22^\circ$, the actuation frequency that maximally reduces the reversed-flow bubble size does not coincide with the frequency leading to the highest aerodynamic improvements in $\overline {C_L}$ and $\overline {C_L/C_D}$.
The baseline flow exhibits high levels of wake fluctuations across a significant portion of the wingspan, as shown in figure 16(a). The spatial support of the resolvent modes employed for flow control is also distributed over the wingspan. Forcing-response mode pairs are primarily concentrated over the quarter-span ($St \le 0.18$), the wing root ($0.18 < St < 0.28$) and the wing tip ($St \ge 0.28$). Actuation using forcing modes at frequencies $St \ge 0.28$ introduces flow perturbations near the tip region but proves ineffective in modifying the wake or enhancing the overall aerodynamic performance. This is attributed to the absence of a noticeable tip vortex structure in the baseline flow.
For the tapered swept wing $(\lambda,\varLambda = 0.27,30^\circ )$, based on the characteristics of the modal structures and insights gained from flow control discussions in §§ 6.4 and 6.5, we assess the control effects at only two frequencies, $St = 0.14$ and $0.20$. We recall that the largest $(x,y)$ sectional area of the baseline separation bubble for this wing is located at the quarter-span (see § 4.1). For the first actuation frequency using the $St = 0.14$ forcing mode, whose spatial support is present near the quarter-span and within the reversed-flow bubble, perturbations are excited within the reversed-flow bubble, modifying the near wake and reducing the reversed-flow volume, as seen in figure 16(b).
The second frequency of actuation involves wake modification near the wing root region, aiming to assess whether a more significant enhancement in $\overline {C_L}$ and $\overline {C_L/C_D}$ can be achieved by perturbing this area, akin to the effects observed for swept wings. The forcing mode at $St = 0.20$ exhibits higher spatial support over the root region, as seen in figure 16(c). The DNS of the controlled flows at this frequency promotes structures near the wing root, leading to an increased root contribution to the overall lift, as depicted in figure 16(d). Additionally, this actuation results in a greater increase in lift and lift-to-drag ratio compared with the lower-frequency actuation at $St = 0.14$.
The differences in the wake patterns between baseline and controlled flows are not readily apparent from the 3-D depiction of coherent structures in figure 16(b,c). Additionally, controlled flows with $St = 0.14$ and $0.20$ forcing modes achieve approximately $38\,\%$ of contraction of the reversed-flow volume. To delve into the distinctions between baseline and controlled flows, we examine the probed $u_y$ at $(x,y)/c = (3,-0.5)$ over time and frequency in figure 16(e). While omitted here for brevity, we note that the baseline and actuated wakes using the forcing mode at $St = 0.14$ exhibit minimal differences in both temporal and spectral analyses of the probed data.
Notable differences emerge when comparing the probed data of controlled flows at $St = 0.14$ and $0.20$ as the peak frequencies of the controlled flow with the $St = 0.20$ forcing mode shift to a higher $St$ range. Wake vortices exhibit a spanwise split into two shedding modes: near-root vortices synchronized with the actuation frequency and quarter-span vortices with a lower frequency unsynchronized with the actuation frequency. This behaviour induces a low-frequency beating in the lift spectrum. This phenomenon, known as vortex dislocation, has been observed in the wakes of high-aspect-ratio blunt bodies and controlled flows (Eisenlohr & Eckelmann Reference Eisenlohr and Eckelmann1989; Williamson Reference Williamson1989; Zhang et al. Reference Zhang, Hayostek, Amitay, He, Theofilis and Taira2020b). Despite the lower aspect ratio in the present controlled flow, a similar wake pattern emerges due to the interplay between near-tip and near-root shedding structures. Lastly, we note that both $St = 0.14$ and $St = 0.20$ forcing-mode actuation strategies increase lift-to-drag RMS, which is originally $(C_L/C_D)_{RMS} = 0.017$ for the baseline flow. For the controlled flow with the $St = 0.14$ forcing mode, $(C_L/C_D)_{RMS}$ increases to $0.098$, while the root-based actuation at $St = 0.20$ yields a lower $(C_L/C_D)_{RMS} = 0.059$. Again, we note that the control effects for the tapered swept wing at $\alpha = 14^\circ$ and $22^\circ$ are analogous and we have omitted the results for the lower incidence angle for brevity.
6.7. Control of tip vortex around untapered unswept wings
To understand the mechanisms that lead to the tip vortex attenuation, we focus our discussion on the flow over an untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$ at $\alpha = 14^\circ$. We compute the streamwise circulation $\varGamma _x = \int _{C} = \boldsymbol {u} \boldsymbol {\cdot } \text {d}\boldsymbol {l}$, where $C$ is the isocontour of $\overline {\omega _x} = -1$ on the $(y,z)$ plane at varied $x$. To compute $\varGamma _x$, only the isocontours of $\overline {\omega _x} = -1$ aligned at the wing tip at $z/c \approx 2$ are considered. In this manner, we limit the inboard vorticity influence on $\varGamma _x$, caused by the interplay of the tip vortex and the root shedding structures. Our discussions focus on wake modifications relative to the baseline and are not significantly influenced by the specific value of the $\overline {\omega _x}$ isocontour used to compute the circulation.
Let us analyse the specifics of the $St = 0.06$ forcing-mode actuation. This actuation results in $8\,\%$ reduction in tip vortex length, as shown in figure 17(c), compared with the baseline length shown in figure 17(b). As seen in the vorticity contours at $x/c = 3$ in figure 17(e), this low-frequency actuation has minimal impact on the core of the tip vortex near the wing because its perturbations arise over the inboard region of the flow, increasing unsteadiness locally. This inboard wake interacts with the tip vortex downstream increasing its dissipation, as shown by the higher decay rate of circulation $\mathrm {d}|\varGamma _x|/\mathrm {d}\kern0.06em x$, resulting in an overall reduction in the tip vortex length.
When employing tip-based actuation at $St \ge 0.22$, the resulting flows exhibit a substantial attenuation of the tip vortex. The controlled flow with the $St = 0.26$ forcing mode achieves a remarkable reduction in tip vortex length, reaching approximately $42\,\%$, as depicted in figure 17(d). Examining the vorticity contours at $x/c=3$ in figure 17(e), we reveal that the actuation associated with the $St=0.26$ forcing mode effectively modifies the vortex core near the wing. This modification is predominantly observed in the lower portion of the vortex core between $-0.5 \le y/c \le -0.25$, as a consequence of this forcing-mode actuation being localized on the pressure side of the wing.
For controlled flows with $St = 0.32$, circulation near the wing is reduced, as illustrated by the vorticity contours at $x/c=3$. However, this forcing-mode actuation is suboptimal for reducing the tip vortex length downstream in the wake. The structures excited by the $St = 0.32$ actuation remain coherent downstream, resulting in a lower circulation decay rate. It is noteworthy that the resolvent-analysis-based control achieves substantial tip vortex attenuation for $St \ge 0.26$ while also maintaining the increases in $\overline {C_L}$, $\overline {C_D}$ and $\overline {C_L/C_D}$ within $6\,\%$ difference from the baseline flow, as demonstrated in table 1.
Similar results were obtained when investigating tip vortex attenuation for an untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$ at $\alpha = 22^\circ$. For this case, the optimal actuation for tip vortex attenuation is identified for the tip-dominant forcing mode at $St = 0.40$, leading to a sizeable reduction in the tip chord length of approximately $60\,\%$. In the Reynolds number regime considered herein, the analysis of tip vortex attenuation is conducted for untapered unswept wings, given that tapered swept wings $(\lambda,\varLambda = 0.27,30^\circ )$ lack a distinct streamwise vortex core at the wing tip, as shown in figure 5.
7. Conclusions
We performed DNS involving external actuation with optimal forcing modes identified through triglobal resolvent analysis. The baseline flows for all cases exhibited a large stalled flow region on the suction side of the wing. Our investigation identifies structures capable of modifying the separated wake, consequently enhancing the overall lift of the wing. For laminar separated flows, the emergence of coherent structures near the wing was found to positively impact aerodynamics. Active control through direct wake modification was demonstrated to improve the lift and lift-to-drag ratio of laminar post-stall flows over low-aspect-ratio wings, with the specific strategy depending on the wing planform and the reversed-flow bubble topology.
For an untapered unswept wing $(\lambda,\varLambda = 1,0^\circ )$, actuation near the root region with frequency content close to that of the baseline vortex shedding, significantly reduced the reversed-flow volume. With the bubble contraction, this actuation induced unsteady vortical structures closer to the wing, leading to a substantial increase in overall lift. At higher frequencies, optimal forcing modes appeared in the vicinity of the wing tip, originating from the trailing edge at the pressure side. Flows actuated using these modes exhibited an unsteady helical vortex formation, suppressing the quasi-steady streamwise vortex core seen in the baseline flow. While the tip vortex circulation decayed at any distance from the wing, modest effects were observed on the inboard wake.
The application of direct wake modification to untapered and tapered swept wings $(\varLambda = 30^\circ )$ was also guided by the insights of forcing-response mode pairs and baseline flow physics. High-frequency actuation using forcing modes with higher spatial support near the wing root of both untapered and tapered swept wings induced unsteadiness that modified the near wake, leading to increased lift and lift-to-drag ratio. Our study also highlighted the utility of response modes and their modal Reynolds stresses for an a priori assessment of control effects. Overall, our findings underscore the receptiveness of laminar separated flows to external perturbations, demonstrating that the optimal spatial–temporal input can significantly alter the 3-D dynamics of the wake and improve the aerodynamic performance of the wing.
Acknowledgements
We thank Professors Y. Sun, V. Theofilis and M. Amitay for enlightening discussions. We also thank the anonymous referees for providing constructive comments that significantly improved the quality of this paper. Computational resources were provided by the High Performance Computing Modernization Program at the US Department of Defense and the Texas Advanced Computing Center.
Funding
We acknowledge the support from the US Air Force Office of Scientific Research (program manager: Dr G. Abate, grant: FA9550-21-1-0174).
Declaration of interests
The authors report no conflict of interest.
Appendix A. Force element analysis
Force element analysis (Chang Reference Chang1992) identifies flow structures that exert aerodynamic loads on the wing. This method shares close similarities with force elements derived through a variational approach (Quartapelle & Napolitano Reference Quartapelle and Napolitano1983), force partition methods (Menon & Mittal Reference Menon and Mittal2021) and many others. In the present approach we define an auxiliary potential with a boundary condition of $-\boldsymbol {n} \boldsymbol {\cdot }\boldsymbol {\nabla } \phi _i = \boldsymbol {n} \boldsymbol {\cdot } \boldsymbol {e}_i$ set on the wing surface, where $\phi$ is the auxiliary potential, $\boldsymbol {n}$ is the unit wall normal vector and $\boldsymbol {e}_i$ is the unit vector in the $i$th direction. By taking the inner product of the Navier–Stokes equations with $\boldsymbol {\nabla } \phi$ and performing an integral over the fluid domain, the forces exerted in the $i$th direction can be expressed as
where the first integrand represents the volume force elements and the second integrand corresponds to the surface force elements. To illustrate the lift elements in the flow field, we take the Hadamard product of the gradient of the auxiliary potential $\boldsymbol {\nabla } \phi _i$ and the Lamb vector ($\boldsymbol {\omega } \times \boldsymbol {u}$). For instance, the resulting $(\boldsymbol {\omega } \times \boldsymbol {u}) \boldsymbol {\cdot }\boldsymbol {\nabla } \phi _y$ variable is often called the lift element. At $Re_c = 600$, the volume elements tend to dominate the contribution to the total force exerted over the wing.