Fuel Burn Evaluation of a Transonic Strut-Braced-Wing Regional Aircraft Through Multipoint Aerodynamic Optimisation

This paper presents a relative fuel burn evaluation of the transonic strut-braced-wing conﬁguration for the regional aircraft class in comparison to an equivalent conventional tube-and-wing aircraft. This is accomplished through multipoint aerodynamic shape optimisation based on the Reynolds-averaged Navier-Stokes equations. Aircraft concepts are ﬁrst developed through low-order multidisciplinary design optimisation based on the design missions and top level aircraft requirements of the Embraer E190-E2. High-ﬁdelity aerodynamic shape shape optimisation is then applied to wing–body–tail models of each aircraft, with the objective of minimizing the weighted-average cruise drag over a ﬁve-point operating envelope that includes the nominal design point, design points at ± 10% nominal C L at Mach 0.78, and two high-speed cruise points at Mach 0.81. Design variables include angle of attack, wing (and strut) twist and section shape degrees of freedom, and horizontal tail incidence, while nonlinear constraints include constant lift, zero pitching moment, minimum wing and strut volume, and minimum maximum thickness-to-chord ratios. Results show that the multipoint optimised strut-braced wing maintains similar features to those of the single-point optimum, and compromises on-design performance by only two drag counts to achieve up to 11.6% reductions in drag at the o ↵ -design conditions. Introducing low-order estimates for approximating full aircraft performance, results indicate that the multipoint optimised strut-braced-wing regional jet o ↵ ers a 13.1% improvement in cruise lift-to-drag ratio and a 7.8% reduction in block fuel over a 500 nmi nominal mission when compared to the similarly optimised Embraer


Introduction
Growing demands for a more environmentally sustainable aviation industry has motivated the search for greener aircraft technologies that can provide step changes in fuel e ciency and emissions. One promising technology is the strut-braced-wing configuration (1) , which has the potential to provide significant improvements to fuel e ciency through a high aspect ratio wing that is supported by a structurally e cient truss topology consisting of a main strut and sometimes one or more jury struts (i.e., the more general truss-braced wing). Given the compatibility of its unconventional wing system with conventional fuselage and empennage designs, and that the configuration leaves open the possibility of integration with many other new and emergent technologies, the strut-braced wing represents a reduced risk configuration technology that has a high potential for contributing to a more environmentally friendly aviation industry. Given this potential, the strut-and truss-braced-wing configurations have been the focus of much research over the past few decades, with many of these investigations focusing on the design and performance of the technology through low-order multidisciplinary design optimisation (MDO) (2,3,4,5,6,7) -demonstrating significant fuel burn savings for the single-and twin-aisle classes of aircraft. Recognizing these potential advantages, NASA and Boeing have since initiated investigations into a Mach 0.70 truss-braced-wing single-aisle aircraft similar to the Boeing 737-800 (8) , with some consideration toward hybrid electric variants as well (9) . Other examples include ONERA (10) and DLR (11) , who investigated strut-and truss-bracedwing single-aisle aircraft at Mach 0.75 and Mach 0.72, respectively. Concerns over losses in airline productivity and compatibility with current air tra c management, however, have since motivated research into strut-and truss-braced wings at more conventional transonic speeds. For NASA and Boeing, this has culminated first in the development of a Mach 0.745 (12) variant, and then a variant for Mach 0.80 (13) .
At these higher and more conventional transonic Mach numbers, however, several design challenges emerge, which must be addressed if the strut-or truss-braced-wing configuration technology is to be demonstrated as a viable option. For example, the reduced thickness and increased flexibility of the high aspect ratio wing can make it more vulnerable to transonic aeroelastic instabilities such as flutter (14) . Researchers must also consider unconventional aeroelastic deflections that are unique to the strut-braced wing topology (15) .
Another concern, which arises earlier in the preliminary design stage, involves the aerodynamic design of the junctions between the wing and strut(s), which emulate transonic channels that can lead to shock formation and boundary-layer separation. If not addressed, this can lead to severe drag penalties, resulting in significant reductions in the overall fuel burn savings of the configuration. Indeed, such a phenomenon can even occur at low transonic Mach numbers, which gave rise to the Platform for Aircraft Drag Reduction Innovation (PADRI) workshop, presenting a Mach 0.72 single-aisle class research platform for addressing these concerns. Some proposed solutions included passive flow control features such as the Kuchemann carrot and shock control bumps (16) , which echo the e↵orts made by Boeing to investigate strut pylons and typhoon fairings (12) . While demonstrating the potential for reducing some of the adverse e↵ects within the wing-strut junction(s), however, these approaches remain largely unproven.
As an alternative, aerodynamic shape optimisation based on the Euler or Reynolds-averaged Navier-Stokes (RANS) equations provides a means for mitigating shock formation through an automation of the shape design process that is driven by simulations of the flow physics. For methods based on the RANS equations, aerodynamic shape optimisation can also capture and address boundary-layer separation, while trading between induced drag, viscous drag, and wave drag to achieve a minimum drag solution. For optimisation problem formulations with limited geometric freedom, i.e., design variables and constraints are strictly defined, aerodynamic shape optimisation can be a reliable and e cient means for refining a baseline design. Conversely, problem formulations involving more general geometric degrees of freedom and constraints can allow for a more exploratory approach to the design problem, providing the opportunity to uncover novel design features that may be more suitable for handling unconventional flow phenomena. With the adjoint method (17,18) for gradient-based optimisation, such an approach to aerodynamic shape optimisation can be performed e ciently, even when considering optimisation problems with hundreds of design variables. Some work has been done previously using high-fidelity aerodynamic shape optimisation toward the aerodynamic design challenges of the transonic strut-braced wing. For example, Gagnon and Zingg (19) applied an optimisation method based on the Euler equations to the aerodynamic design of a Mach 0.78 strut-braced-wing regional jet, demonstrating that a low induced drag design can be achieved with a mitigation of the adverse e↵ects within the wing-strut junction region. Given the inviscid nature of the Euler equations, however, trades with viscous drag could not be accounted for, leaving open the question of whether a low total drag transonic strut-braced-wing aircraft can be achieved. This issue was addressed in part by a study done by Secco and Martins (20) , which involved the application of aerodynamic shape optimisation based on the RANS equations to the PADRI strut-braced-wing geometry, demonstrating that the transonic interference e↵ects can be largely eliminated, while achieving a lift-to-drag ratio of around 20 for the wing-strut-fuselage model. With the PADRI concept designed for Mach 0.72, however, uncertainties surrounding the aerodynamic performance of the configuration still remain at more conventional transonic Mach numbers.
Furthermore, strut-and truss-braced wings, which benefit from low induced drag via their larger wing spans, typically prefer to operate at higher lift coe cients. This leads to a rebalancing of the induced drag and viscous drag components in order to achieve more optimal lift-to-drag ratios (21) . Given that the previous studies were limited to conventional lift coe cients, the question that remains to be addressed, therefore, must also consider transonic strut-and truss-braced-wing aircraft operating at higher and more optimal lift coe cients. An evaluation of the fuel e ciency of such optimised concepts must also be included, which requires an assessment of the impact that the optimised design features have on the system performance of the aircraft.
In an attempt to address these concerns, Chau and Zingg (22) developed a representative Mach 0.78 strut-braced-wing regional jet based on the design missions and top level aircraft requirements of the Embraer E190-E2 through low-order conceptual MDO. Aerodynamic shape optimisation based on the RANS equations was then applied to its aerodynamic design, with results indicating that a low drag transonic design can be achieved even at a cruise lift coe cient of 0.682. With current technology levels assumed, an estimate of the block fuel over a 500 nmi nominal mission demonstrated a 7.6% savings when compared to a similarly optimised conventional tube-and-wing aircraft representing the Embraer E190-E2. Such a result suggests the possibility of designing a fuel e cient transonic strut-braced-wing aircraft for the regional aircraft class. However, since transport aircraft are typically expected to maintain their performance over a range of cruise lift coe cients and Mach numbers, a more robust design is necessary, which is often achieved through on-design performance compromises for improvements at o↵-design conditions. This can prove to be especially challenging for the transonic strut-braced wing given its susceptibility to shock formation.
The primary objective of the present paper, therefore, is to extend the previous study by considering a range of cruise lift coe cients and Mach numbers to determine if the low drag performance can be maintained, and to provide a more credible estimate of the fuel burn benefit o↵ered by the transonic strut-braced-wing configuration for the regional aircraft class. Toward this end, multipoint optimisation is performed for a strut-braced-wing aircraft based on the Embraer E190-E2, as well as a conventional tube-and-wing representing the same reference aircraft for performance comparisons. Emphasis is placed on including first-order e↵ects that have significant impacts on the design parameters of each aircraft with regard to cruise performance and block fuel. Other design considerations such as low-speed aerodynamics, high-speed bu↵et, and flutter, which are also important toward demonstrating the viability of the configuration, are not included, as they are expected to either impact each aircraft similarly, or to provide only higher-order e↵ects on performance. Current technology levels will also be assumed in order to focus on the benefits of the configuration technology itself. As a secondary objective, the present paper will also investigate the aerodynamic design features that contribute to a successful transonic strut-braced-wing regional jet, with comparisons be-tween single-point and multipoint optimised designs.
The paper is organized as follows. Section 2 provides an overview of the approach for evaluating the relative fuel burn performance of the transonic strut-braced-wing configuration, while Section 3 presents the aircraft characteristics of the strut-braced-wing and conventional tube-and-wing regional jets. The high-fidelity aerodynamic shape optimisation framework used to perform multipoint optimisation is described in Section 4, with the optimisation problem formulations included in Section 5. Results, and conclusions and future work are presented in Sections 6 and 7, respectively.

Approach to Evaluating Aircraft Fuel Efficiency
Representative aircraft concepts are developed through the application of a conceptual MDO framework (22) , which consists of low-order models for aerodynamics, structures, weight and balance, propulsion, and performance -providing a means for capturing most of the firstorder e↵ects that are relevant to cruise performance and block fuel. The objective of each MDO problem is to achieve a minimum block fuel design over a nominal range mission at a cruise Mach number of 0.78. This represents a typically-flown mission for the Embraer E190-E2, and is separate from the design missions used to size the design weights of each aircraft, as described in Ref. (22) .
For the strut-braced-wing concept, design variables are focused on the sizing and optimisation of the wing, strut, horizontal and vertical tails, propulsion system, and operating conditions. For the wing and tail systems, design variables include the root and tip chord lengths and thickness-to-chord ratios of each wing, strut, and tail segment. Constraints on these degrees of freedom include a maximum design wing loading, which places a lower bound on the wing area for takeo↵ and landing considerations based on the Embraer E190-E2; a minimum fuel volume, which maintains a minimum wing and strut outer mold line (OML) for the fuel tanks based on the maximum fuel weight (MFW); and minimum tail volume ratios based on a reference T-tail design. Other wing and strut parameters such as span, sweep, and dihedral, as well as the attachment locations of the strut with the wing and fuselage, are not included since they are assumed to have a strong dependence on structures and aeroelastic phenomena such as flutter, going beyond the capabilities of the low-order models. These parameters are set based on reference concepts found in Bradley et al. (8) .
Another design variable for the strut-braced-wing concept is a maximum thrust parameter for resizing the propulsion system, which is constrained by a minimum thrust-to-weight ratio also based on the Embraer E190-E2, and top-of-climb excess thrust requirements. Initial cruise altitude design variables are also included for each design mission, which help determine the optimum cruise C L values for minimum block fuel over the nominal mission. These design variables are constrained by a number of disciplinary e↵ects such as the thrust required at top-of-climb, and tradeo↵s with climb fuel.
For the conventional tube-and-wing configuration, a concept is developed as-drawn, namely, the wing, horizontal and vertical tails, propulsion systems, and operating conditions are defined as closely as possible to the Embraer E190-E2. Given that the wing thicknessto-chord ratios are not publicly available, however, these are included as design variables and are driven toward a minimum block fuel solution while subject to a minimum fuel volume constraint.
Other design considerations for the strut-braced-wing concept include an assumption that the strut produces minimal lift, and hence is developed primarily as a structural member that generates as little drag as possible. The structures of the wing and strut are also constructed from composite materials, which is a technology that is readily available and provides an advantage over the aluminum wing composition of the Embraer E190-E2-like conventional tube-and-wing. Technologies such as natural laminar flow, active flow control, and advanced propulsion systems are not considered, given the objective of isolating the benefit o↵ered by the configuration technology when assuming current technology levels. Additional details on the conceptual design of each aircraft are provided in Chau and Zingg (22) . These concepts are used to create 3D models of each aircraft that include the wing (and strut), fuselage, and horizontal tail. This allows for a multipoint optimisation of each wing and tail system that captures the dominant aerodynamic e↵ects, including the lift and interference drag from the presence of the fuselage. The optimisation of each aircraft is performed for a range of lift coe cients and Mach numbers that include and surround the nominal cruise point. To enable a more exploratory approach to design optimisation, a more general formulation of the constraints is employed to maintain the feasibility of each aircraft. For example, minimum wing (and strut) volume and minimum maximum thickness-to-chord ratio constraints are defined, which together act as surrogates for maintaining a minimum structural depth of the wing (and strut) that is independent of the internal structural topology. These constraints also ensure that there is su cient volume for containing the fuel tanks required to store the MFW.
A construction of the full aircraft performance is then accomplished through a synthesis of the high-fidelity aerodynamic estimates with low-fidelity approximations from the components not modeled in the RANS simulations. The updated cruise fuel approximation can then be combined with the approximations for warmup, taxi, takeo↵, climb, descent, and landing to provide an estimate of the mission block fuel for each aircraft.

Aircraft Characteristics
Aircraft concepts representing the strut-braced-wing and conventional tube-and-wing configurations in the regional jet class, herein referred to as the SBW100 and CTW100, respectively, are developed based on the design missions and top level aircraft requirements of the Embraer E190-E2. This includes a design range and payload of 3,100 nmi and 104 passengers, respectively. As described in Section 2, however, evaluations of cruise performance and block fuel consider a nominal mission with a range of 500 nmi, the design payload, and a Mach number of 0.78. Planform views of the aircraft concepts are shown in Figure 1. Table 1 provides an overview of the aircraft characteristics and their nominal performance based on the low-order models. Compared to the CTW100, the SBW100 has the advantage of a 60% larger wing aspect ratio, which trades e ciently against penalties in added wing wetted area. In order to realize the full potential of this high aspect ratio wing, however, the SBW100 must operate at a much higher cruise C L . For a given wing loading, this results in a significantly elevated cruise altitude. It is important to note, however, that achieving the optimum lift coe cient for maximizing the lift-to-drag ratio must trade with increased climb fuel and potentially higher fuselage weights as a result of increased cabin pressurization loads. These factors are accounted for in the conceptual design process, with the design C L of the SBW100 representing the optimum C L for minimum block fuel.
The SBW100 also has the advantage of a 24.5% lower wing weight compared to the (a) CTW100 (b) SBW100 Figure 1: Aircraft concepts developed through conceptual MDO (22) .
CTW100 owing to the structural e ciency of the strut-bracing and the benefit of composite structures. This is o↵set, however, by an 11.9% heavier fuselage, which comes from weight penalties for fuselage-mounted landing gears and a larger horizontal tail moment arm, which translates to larger fuselage bending loads in the empirical equations. Together, the aerodynamic and structural advantages combine to provide an overall reduction in the design weights of the SBW100. For more details on the aircraft concepts developed through the low-order MDO framework, see Chau and Zingg (22) .

High-Fidelity Aerodynamic Shape Optimisation Framework
The high-fidelity aerodynamic design of each aircraft is performed through the application of an aerodynamic shape optimisation framework called Jetstream that has been developed at the University of Toronto Institute for Aerospace Studies. It consists of an integrated geometry parameterization and mesh-deformation scheme (23,24) , a free-form and axial deformation geometry control system (25) , a structured multiblock Newton-Krylov-Schur flow solver for the RANS equations fully coupled with the Spalart-Allmaras turbulent model (26) , the discreteadjoint method for flow-and mesh-dependent gradient evaluation (17,18) , and SNOPT (27) for gradient-based optimisation. In the following sections, a brief description of each component is provided.

Integrated Mesh Parameterization and Deformation
In order to update the computational grid following a deformation to the aerodynamic surfaces, Jetstream includes an integrated mesh parameterization and deformation scheme (23,24) that can achieve large shape changes at a relatively low computational cost, while maintain- ing the quality of the grid. Given an initial structured multiblock mesh associated with a given baseline geometry, each block is parameterized with cubic B-spline volumes through a chord-length parameterization. This provides a parametric model of the mesh that closely approximates the initial computational grid, and by extension, the aerodynamic surfaces, which maintains consistency throughout the optimisation process. In addition, this parametric model also provides a means of automatically refining the computational grid through grid node insertion and redistribution (24) . This capability is used in the present work to generate a consistent family of grid levels for performing grid convergence studies.
For mesh deformation, a linear elasticity model is applied to each B-spline volume in parallel, where deformations applied to the subset of surface control points defining the aerodynamic surfaces are propagated across each control volume within the computational domain. In order to preserve the quality of the computational grid, the sti↵ness of each element within a given block is defined to be proportional to its volume and a measure of its orthogonality (23) . To accommodate large shape changes, robustness can be further improved by subdividing the deformation into smaller increments of linear elastic changes, thus maintaining the small strain assumption and allowing for intermediate updates to the element sti↵nesses. With the number of B-spline volume control points being 2-3 orders less than the number of nodes in the computational mesh, the deformation of the complete CFD mesh can be achieved at a significantly lower computational cost.

Geometry Control
For controlling the shape of the aerodynamic surfaces, a free-form and axial deformation method (25) is used in which free-form deformation (FFD) volumes provide local or sectional design control and axial curves provide global or planform design control. These FFD volumes are defined as B-spline volumes that can be manipulated through their control points to smoothly deform an embedded object of interest, while the axial curves, defined as B-spline curves, can be similarly controlled to drive the position and orientation of these FFD volumes in space. Within the Jetstream framework, the surface control points that define the aerodynamic surfaces to be deformed are embedded within the FFD volumes rather than their surface discretizations. This results in an e cient two-level deformation system in which geometry control is dissociated from shape representation, maintaining the analytical surface and mesh definitions.
To reduce the number of degrees of freedom to a smaller set of more intuitive design variables, the x-, y-, and z-coordinates of the FFD volume control points are used to define section shape, as well as twist and taper degrees of freedom. These are defined through rotation and scaling operators applied to each FFD-volume cross-section as follows: • Twist: a rotation of the FFD-volume cross-section in the local xz-plane about the local origin • Taper: a uniform scaling of the FFD-volume cross-section in the local xz-plane with respect to the local origin • Section Shape: a scaling of the vertical distance from the local origin to the position of a given FFD-volume control point along the local z-axis; this design variable is defined separately for each individual FFD-volume control point These transformation operators are applied to the initial xyz-coordinates of each FFD-volume cross-section in sequence at each design iteration and follow a cubic interpolation between each FFD-volume control point in the parametric chordwise direction u, a cubic interpolation between each FFD-volume cross-section in the parametric spanwise direction v, and a linear interpolation between each FFD-volume control point pair in the parametric vertical direction w, where the parametric coordinates follow the transformation F (u, v, w) ! (x, y, z).
Attached to each FFD volume is an axial curve that passes through each FFD-volume crosssection and is typically positioned at the leading edge, quarter chord, or trailing edge of a given wing object. Since the FFD-volume cross-sections must remain attached and normal to their associated axial curve based on their initial attachment locations, the axial curves can be manipulated to provide more global changes to the embedded object. The axial curves also define the origins of each local coordinate system with which the FFD volume design variables are defined. These local coordinate systems are oriented with their xz-axes in-plane with each FFD-volume cross-section. In the present paper, the axial curves are primarily used to serve this purpose, and so are generally only defined as linear B-spline curves. In general, however, they can be defined as B-spline curves of any order, and can be manipulated through sweep, span, and dihedral degrees of freedom that are defined through translation operators. Specifically, these design variables are defined as follows: • Sweep: a translation in the x-coordinate of a given axial curve control point • Span: a translation in the y-coordinate of a given axial curve control point • Dihedral: a translation in the z-coordinate of a given axial curve control point For more details on the geometry control system, see Gagnon and Zingg (25) and Chau and Zingg (22) .

Flow Solver
To calculate aerodynamic functionals, Jetstream uses a parallel implicit Newton-Krylov-Schur algorithm (26) for solving the RANS equations fully coupled with the Spalart-Allmaras turbulence model (SA). More specifically, SA-neg (29) is used in conjunction with QCR2000 (30) , the latter of which is included to aid in properly resolving flow separation in and around junction regions (31) .
Second-order spatial discretization is provided by centered di↵erence summation-by-parts (SBP) operators (32) coupled with simultaneous approximation terms (SATs) to enforce boundary conditions and couple block interfaces weakly. Artificial dissipation is included in the form of 2nd-di↵erence and 4th-di↵erence scalar dissipation operators to improve numerical convergence, with the introduction of the 2nd-di↵erence artificial dissipation controlled by a pressure sensor.
The numerical solution to the linearized governing equations is driven toward steady state via an inexact-Newton method. Globalization of the flow solution is performed through pseudo-transient continuation, with the linear system that arises at each Newton iteration solved inexactly using a flexible variant of the Krylov subspace method, generalized minimal residual (GMRES) (33,34) , preconditioned with the approximate-Schur method (35) .
This flow solver has been validated against results from the Fifth Drag Prediction Workshop (DPW5) (31) , with the predicted drag coe cient of the NASA Common Research Model (CRM) agreeing within one drag count of the median across all participants (36) . In the present work, boundary layers are assumed to be fully turbulent.

Gradient Evaluation and Optimisation
Numerical optimisation is performed with SNOPT (27) , a gradient-based optimisation algorithm based on the sequential quadratic programming (SQP) paradigm that can handle largescale constrained optimisation problems with both linear and nonlinear constraints. For gradient evaluation, Jetstream uses the discrete-adjoint method (17,18) for the computation of the objective function gradient, as well as constraint gradients that depend directly on the flow or mesh-deformation equations. For all other constraint gradients, which are predominantly associated with geometric constraints, and sensitivities that contribute to the discrete-adjoint method, analytical calculations are performed, with some quantities approximated through the complex-step method (38) . For more details on the gradient evaluation method, see Osusky et al. (24) .

Optimisation Problem Setup
In the following sections, the problem setup for each high-fidelity aerodynamic shape optimisation is presented. This includes a description of the baseline geometries, which not only serve as the initial designs for each gradient-based optimisation problem, but also determine some of the design variable bounds as described in Section 4.2. An overview of the computational grids, which have been developed to balance grid resolution and computational cost, is also provided. Sections 5.3 and 5.4 then present the multipoint optimisation formulations, and the design variables and constraints, respectively.

Baseline Geometries
For optimisation, the baseline geometries include the wing (and strut), fuselage, and horizontal tail components, with the overall dimensions based on the conceptual designs presented in Section 3. For both aircraft, the fuselage nose and tail sections are modeled based on the OML of the Airbus A220-300 (39) . Similarly, the wing-fuselage fairing for the CTW100 is also modeled based on the A220-300 and scaled to the dimensions of that of the Embraer E190-E2. For the SBW100, however, the wing-fuselage and strut-fuselage fairings are based on those of the PADRI strut-braced-wing geometry (40) , and are repositioned along the fuselage in reference to the concepts presented in Bradley et al. (8) .
For both aircraft, the baseline wing geometries are defined by RAE-2822 airfoil profiles, which provide reasonable starting points for transonic wing design. Symmetric supercritical SC(2)-0012 sections are used for the strut of the SBW100, while SC(2)-0010 profiles are used for the horizontal tail of each aircraft. These optimisation level grids have been generated following the medium mesh gridding guidelines of the Fourth Drag Prediction Workshop (DPW), which are representative of current drag prediction standards (41) . In general, this resolution o↵ers a reasonable tradeo↵ between computational cost and accuracy, while including su cient grid resolution for capturing the relevant flow features. In order to obtain mesh-independent aerodynamic functionals for the initial and optimised designs, Richardson extrapolation is performed with the addition of two finer grid levels, L1 and L2, which have two and four times as many grid nodes as the optimisation-level grid L0, respectively. Table 2 provides an overview of the grid characteristics, with o↵-wall spacings and y + values in reference to the initial designs.

Multipoint Objective
A common approach to multipoint optimisation for the aerodynamic design of an aircraft is to formulate the objective function as a weighted integral over a range of operating conditions in order to improve robustness at o↵-design conditions across a range of operating parameters (42) . For example, a weighted integral over the Mach number and C L design space can be defined as where D(M, C L ) are user-defined design weights that can be used to place more priority on nominal operating points that are expected to be encountered more frequently over the operating envelope. This integral can be approximated through a quadrature method given by (43) J = where w i, j are the weights of the quadrature method. This approach is useful when aerodynamic shape optimisation is used in the context of designing a real and very robust aircraft, especially when the nominal design point is complemented by other design points that provide constraints related to low-speed aerodynamics, high-speed bu↵et, and flutter. In the present paper, however, the objective is to assess the relative performance of the transonic strut-braced-wing configuration while accounting for a range of cruise conditions, especially at higher Mach numbers with respect to the nominal value of 0.78, and while ignoring higherorder e↵ects. For this purpose, it is su cient and less costly to consider a small and discrete set of operating conditions that includes multiple C L values and higher Mach numbers. Although point-optimisation at each of the design points can lead to excessively optimistic estimates of the overall performance of a given aircraft, several studies have suggested that robust designs can be achieved with a modest number of discrete operating conditions in a multipoint optimisation problem formulation (44,45) . To this end, a five-point multipoint optimisation is considered that consists of the nominal operating point, two operating points subjected to a ±10% change in C L from the nominal point, and two high-speed conditions with a +0.03 change in Mach number from the nominal Table 3: Single-point (22) and multipoint optimisation design weights and operating conditions. point at 10% and 20% C L . These design points cover a range of expected operating conditions with an emphasis on those most likely to lead to significant wave drag penalties. The objective function is then given by where the design weights are selected such that the nominal operating condition has a two-fold priority over all other design points. The design points considered are listed in Table 3.

Design Variables and Constraints
Design variables include the angle of attack, as well as geometric degrees of freedom provided by the free-form and axial deformation geometry control systems shown in Figure 2. For the CTW100, the parameterized wing and horizontal tail are each embedded within FFD volumes with 12 and 4 FFD-volume cross-sections, respectively, each consisting of 11 FFD-volume control point pairs. For the wing, these provide twist and section shape design variables, while for the horizontal tail, section shape design variables are omitted to maintain a symmetric design, and the twist design variables are linked across the FFD volume to provide incidence angle control. Axial curves are positioned at the quarter chord of each FFD volume, and hence each lifting surface, which define the local coordinate system for the twist and section shape design variables. A similar setup is used for the SBW100. The FFD volume of the wing consists of 19 FFDvolume cross-sections for the same number of cross-sections per unit span, with additional cross-sections introduced near the wing-strut junction to provide su cient geometric control for addressing the transonic interference e↵ects. Additional FFD volumes are also included to embed the main and vertical strut surfaces, as well as the transition strut, which connects the end of the main strut to the start of the vertical strut. These strut segments are shown in the inset of Figure 2b. As with the CTW100, each FFD-volume cross-section consists of 11 control point pairs, which provide twist and section shape design variables for the wing and strut. The incidence angle of the horizontal tail is also included as a design variable, and axial curves are positioned at the quarter chord of each lifting surface. A novel junction deformation scheme is also included to enable the optimisation of the wing-strut junction where the geometry control system of the wing and strut intersect (22) . Similar junction deformation schemes are also included at each fuselage intersection, where changes in the geometry over the embedded aerodynamic surfaces are propagated across the fuselage patches of each aircraft (24) . This allows for changes to the overall incidence angle of each lifting surface, and is specifically used to define the incidence angle degree of freedom for each horizontal tail. Table 4 provides a summary of the design variables involved in each problem, as well as their bounds.
For simulating steady, level flight, each multipoint optimisation problem includes nonlinear constraints for maintaining a constant lift and zero pitching moment. The pitching moment constraint, which would be considered at all operating conditions if elevators were modeled, is included only at the nominal design point for each aircraft. As mentioned in Section 2, minimum volume and minimum (t/c) max constraints are also included, which take the form of nonlinear constraints. A number of linear geometric constraints are also included to further constrain the design space. For example, the minimum distance between each chordwise pair of FFD-volume control points is limited to 50% of its baseline value, while fixed leading-and trailing-edge constraints are included to prevent shear twist and the translation of each FFD-volume crosssection. Other linear geometric constraints are included to help simplify the design of the strut near the wing-strut junction. These include a constant twist constraint for the vertical strut FFD-volume cross-sections, and a linear interpolation twist constraint across the FFDvolume cross-sections of the transition strut. A linear interpolation twist constraint is also applied across the three wing FFD-volume cross-sections across the wing-strut junction to prevent the optimiser from introducing a very sudden wash-in to compensate for the local loss of sectional lift caused by the presence of the strut. A summary of the linear and nonlinear constraints is provided in Table 5.

Optimisation Results
The SNOPT optimisation histories for each multipoint optimisation problem are shown in Figure 3. The parameters are Optimality -a measure of the objective function and constraint gradients, Feasibility -a measure of the constraint violations, and the Merit Function, which represents the objective function when constraint violations are minimized. Each optimisation is considered converged when the Merit Function changes by less than a drag count over 10 or more function evaluations, Optimality has been reduced by approximately two or more orders of magnitude, and Feasibility has been satisfied to a tolerance of at least 10 4 . For both cases, these requirements are met following 55-60 major iterations or 60-70 function evaluations, with more than 95% of the drag reductions achieved within the first 25-30 major iterations.
In order to obtain accurate predictions of the cruise drag at each design point of each multipoint optimised design, grid-converged C D values are estimated through Richardson extrapolation, using the L0, L1, and L2 grid levels described in Section 5.2. The data points are shown in Figure 4, where the convergence of C D is monotonic for all cases. This is a necessary condition for the application of Richardson extrapolation. Although the errors in C D associated with the L0 grid level are seen to be significant, C D converges consistently across each grid level, and the relative performance is maintained as the grids are refined. As such, the multipoint optimised designs obtained on the L0 grid level can be expected to be closely comparable to those optimised on a finer grid level. For comparisons, Figure 4 also includes grid convergence studies for the single-point optimised designs, evaluated at each Constrains the minimum wing (and strut) OML volume based on fuel storage requirements (nonlinear) Minimum (t/c) max 10 30 Minimum maximum thickness-to-chord ratio constraints based on structural requirements (nonlinear) Minimum t/c scaling 132 418 Constrains the local vertical separation between each pair of FFD-volume control points to be greater or equal to 50% of its initial value (linear) Fixed LE/TE 24 76 Constrains section shape design variables at the leading-and trailing-edges to be equal and opposite between the lower and upper FFDvolume control points (linear) Linked junction wing twist 0 1 Interpolates the twist design variable across the 9th and 11th wing FFD-volume cross-sections (linear) Linked horizontal tail twist 1 1 Links the twist design variables of the horizontal tail to translate to incidence angle control (linear)  Table 6 includes the aerodynamic performance of each multipoint optimised aircraft, with results from the single-point optimisations of Chau and Zingg (22) also included for compar-  isons. Based on the high-fidelity models of each aircraft, the results indicate that the multipoint optimised SBW100 provides a 9.8% improvement in cruise L/D and a 13.2% reduction in cruise drag over the multipoint optimised CTW100. Compared to the single-point optimised designs, the multipoint optimums show a similar relative benefit with a 0.3% improvement in both cruise L/D and drag at the nominal design point, despite an increase in C D by 2 counts for both aircraft.
In order to obtain estimates for the full aircraft performance, low-order approximations for the drag of the aircraft components not included in the high-fidelity models are introduced, namely, for the vertical tail, nacelles, and pylons of each aircraft. Skin friction drag mark-ups (a) CTW100 single-point optimum.
(d) SBW100 multipoint optimum. of 5% are also applied to approximate contributions from airframe excrescences. These results are also presented in Table 6 and indicate a 13.1% improvement in cruise L/D and a 15.7% reduction in cruise drag at the nominal design point for the multipoint optimised SBW100, relative to the similarly optimised CTW100. Compared to the single-point optimised aircraft, this represents a 0.2% improvement in both relative aircraft cruise L/D and drag. These results suggest that a low drag strut-braced wing can be achieved over a range of cruise conditions, especially since the performance benefits appear to be robust to o↵-design conditions at higher Mach numbers and lift coe cients. For approximating the block fuel for each nominal range mission, estimates of weight and TSFC are calculated through the low-order models, along with the fuel contributions from warmup, taxi, takeo↵, climb, descent, and landing, which are assumed to remain constant. This provides a block fuel savings of 7.8% for the multipoint optimised SBW100 when compared to the Embraer E190-E2-like CTW100. Compared to the aircraft designs obtained from single-point optimisation, this represents a further relative reduction of 0.2% since the drag increase experienced by the CTW100 when designed for multiple cruise conditions is marginally higher than that of the SBW100.
Comparisons of the drag performance between the single-point and multipoint optimised designs over the five design points of each aircraft are shown in Figure 5. Here, it can be seen that the nominal performance degradation of 2 drag counts for both aircraft leads to an improvement in aerodynamic performance at the o↵-design conditions. For design points 2 and 3, the performance improvements are on the order of 1% and 2.5%, respectively, for each aircraft, while improvements of approximately 10-12% are achieved at design points 4 and 5. This illustrates that for both aircraft, a low drag can be maintained at the o↵-design cruise conditions, with significant improvements specifically at the high-speed design points, without the introduction of significant compromises to on-design performance. Table 7 presents approximations for the full aircraft performance of each aircraft at each of the design points. These results are obtained by adjusting the fixed weight of each aircraft at each operating condition such that the start of cruise C L matches the C L of each design point. Changes to the weight of the aircraft due to changes in the fuel required at warmup, taxi, takeo↵, climb, descent, and landing, as well as to the fuel reserves, are accounted for. Overall, the improvements in cruise L/D and drag at the o↵-design conditions range from 14-16% and 11-13.5%, respectively. From Figure 6, the savings in block fuel obtained for the missions associated with each design point remain consistent at around 7-8%. Figure 7 shows the multipoint optimised spanwise lift distributions for each aircraft operating at the nominal design point, with those of the single-point optimised designs included for comparisons. For all cases, the optimised net spanwise lift distributions are elliptical in form but shifted inboard due to the presence of the trim constraint and the presumed avoidance of high outboard sectional lift coe cients that can lead to increased wave drag penalties. Moreover, the multipoint optimised spanwise lift distributions feature further inboard shifts, which are compensated by modest increases in the negative lift over each horizontal tail. Of interest, however, is that for the multipoint optimised SBW100, the inboard shift is the result of a moderate increase in positive lift over the strut, which allows the main wing to reduce its loading. This feature likely enables an improvement in performance over the high-speed design points where the cruise C L values are much lower, while aiding in reducing the overall wing loading for the high C L design point. Such a benefit suggests that lifting struts are aerodynamically favorable for transonic strut-braced wings, and may explain in part why Boeing has opted to incorporate and emphasize such a feature when transitioning from their Mach 0.70 design (8) to their Mach 0.745 (12) and Mach 0.80 variants (13) . It should be noted, however, that lifting struts can lead to structural design challenges associated with the impact of non-axial loads on buckling. Additional aerodynamic design features are presented next, first for the CTW100 and then for the SBW100. For the CTW100, an overview of the multipoint optimised design features and flow characteristics at the nominal design point is shown in Figure 8, with the singlepoint optimisation results included for comparisons. From Figure 8a, it can be seen that the optimiser has allowed some shock surfaces to return over the upper surface of the wing, although these shocks are relatively weak with upstream Mach numbers less than Mach 1.1. This is consistent with the relatively small drag increase of 2 counts when optimising for multiple design points rather than one. Figure 8c shows optimised airfoil profiles and pressure distributions at di↵erent spanwise stations across the wing. At the majority of the spanwise stations, the leading-edge suction peaks are reduced to favor more aft loading. At stations 2y/b = 30%, 45%, and 60%, a noticeable decrease in mid-chord loading can also be seen, which may be tied to the more favorable aerodynamic performance at the o↵-design cruise conditions. Figure 9 shows the single-point and multipoint optimised airfoil profiles and pressure distributions at the same spanwise locations, but for design points 2 and 4, which are two of the more challenging o↵-design cruise conditions. For the +10% C L design point, the pressure distributions are similar in form to those of the nominal design point, except here, it can also  be seen that their features contribute to significant reductions in the strength of the shocks present over the single-point optimised design. For the pressure distributions at the Mach 0.81 design point, it can be seen that the design features help in reducing the suction peak while also reducing the favorable pressure gradient that begins near 50% chord and terminates around 65% chord. This also results in a shock strength reduction.
An overview of the design features and flow characteristics for the multipoint optimised SBW100 is provided in Figure 10, with the single-point optimised design and flow features included for comparisons. As with the CTW100 optimisations, the multipoint optimised design experiences an increase in wave drag due to the return of shocks over the wing upper surface. Once again, however, the upstream Mach numbers associated with these shock surfaces are all less than Mach 1.1, indicating that they are weak and have a small e↵ect on drag. Shock surfaces present within the junction of the baseline wing and strut presented in Chau and Zingg (22) also remain eliminated for the multipoint optimised SBW100, even when accommodations are made to preserve o↵-design aerodynamic performance. Based on the pressure distributions, it can be seen that the weak shocks over the wing are positioned close to 50% chord. For the strut, the pressure distribution at 15% semispan illustrates an increase in lift, which is achieved through a minor increase in geometric twist. Figure 11 shows the pressure distributions for the high C L design point, as well as those of the first high-speed cruise condition. Here, the same trends as those of the CTW100 can be observed, but with the pressure distributions adjusted to compensate for the higher overall lift requirements. In fact, the multipoint optimised pressure distributions suggest a higher wave drag penalty based on the magnitude of the change in pressure coe cient over the steep pressure recovery regions when compared to those of the CTW100. However, the total drag savings o↵ered by the SBW100 suggests that this penalty is outweighed by savings in induced and viscous drag. At the high-speed design point, the pressure distributions are also quite similar to those of the CTW100. As expected, the lift carried by the strut also appears to scale with C L . Inner and outer views of the wing-strut junction designs from single-point and multipoint optimisation are shown in Figure 12. These include surface pressure distributions, as well as airfoil profiles and pressure distributions at four stations along the wing, and four stations along the transition and vertical strut segments. For clarity, these airfoil profiles have not been rotated with respect to the angle of attack, as has been done in the previous figures. Here, the surface pressures at the nominal cruise condition are generally smooth and free of adverse effects for both designs. This is consistent with the absence of shocks within the junction region shown in Figure 10. The overall section designs are also quite similar between the two optimisations. For the wing, exceptions include small di↵erences in airfoil shape toward the leading edge as seen in sections C and D, and an overall reduction in sectional lift, corresponding to the reduction in wing loading observed in the spanwise lift distributions. For the strut, a minor reduction in outwards force distribution can be seen for the multipoint optimum. The overall similarities between the single-point and multipoint optimised designs indicate that both the novel airfoil shapes, and the outwards force distribution are not necessarily point-designed features, and are likely to be key contributors to low drag transonic strut-braced-wing designs that are more robust to changes in operating conditions.

Conclusions and Future Work
Toward a more credible estimate of the fuel burn benefit associated with the transonic strutbraced-wing configuration at conventional Mach numbers, and higher and more optimal lift coe cients, this paper presents an investigation of a Mach 0.78 strut-braced-wing regional jet with a lift coe cient of 0.682 through the application of multipoint aerodynamic shape optimisation based on the RANS equations. This aircraft is developed as a representative concept for the configuration based on the design missions and top level aircraft requirements of the Embraer E190-E2 through the application of a low-order conceptual design environment. For performance comparisons, a conventional tube-and-wing aircraft is also included, which represents the Embraer E190-E2 as a modern best-in-class regional jet.
Given the importance of addressing the transonic interference e↵ects of the strut-braced wing, which become more di cult to overcome at high transonic Mach numbers, the present paper considers multipoint optimisation with the nominal design point, design points at ±10%  nominal C L at Mach 0.78, and two Mach 0.81 design points at 10% and 20% nominal C L . These optimisations consider the wing-body-tail models of each aircraft, with results indicating that low drag performance at each design point can be maintained, achieving up to 10-12% reductions in o↵-design cruise drag compared to single-point optimised designs, while only compromising on-design performance by less than 1%. Aerodynamic design features that contribute to the robustness and e ciency of the transonic strut-braced wing include an outwards force distribution over the strut near the wingstrut junction, and novel wing sections, which together aid in mitigating the transonic channel e↵ect, and hence shock formation and boundary-layer separation. Away from the wing-strut junction region, the optimised strut-braced wing is found to feature a moderately lifting strut, which enables a reduction in inboard wing loading for improving aerodynamic performance at higher Mach numbers and higher lift coe cients.
Introducing low-order estimates for constructing approximations for full aircraft performance that include drag contributions from the vertical tails, nacelles, and pylons, the transonic strut-braced-wing regional jet is found to provide a 13.1% improvement in cruise liftto-drag ratio over the similarly optimised conventional tube-and-wing aircraft. Further introducing low-order estimates for the fuel required for warmup, taxi, takeo↵, climb, descent, and landing, this translates to a 7.8% savings in block fuel over a 500 nmi nominal mission. Similar fuel burn savings are maintained over each of the o↵-design conditions, with estimates ranging from 7 to 8%.
Given the relatively high cruise altitudes needed to achieve the optimal design C L , one would expect a larger fuel burn benefit when considering a longer range nominal mission. For example, as a first-order estimate, updates to the low-order approximations, namely, the nonaerodynamics and non-cruise block fuel contributions, results in a relative fuel burn benefit of 10.8% for a 1,000 nmi mission. Another consideration is the question of how much of a benefit is attributed to the advantage of composites. Given that the CTW100 is intended to represent the Embraer E190-E2, its wing structures were modeled with aerospace-grade aluminum. However, if a variant of the CTW100 is considered with a composite wing structure, loworder approximations indicate that the relative fuel burn benefit of the multipoint optimised SBW100 reduces to 6.8% for the nominal range mission.
For further improving the reliability of fuel burn estimates associated with the transonic strut-braced-wing configuration for the regional aircraft class, future work will include highfidelity aerostructural optimisation for investigating parameters such as wing span and sweep, and wing-strut junction location, as well as the advantages of adding one or more jury struts. Toward this end, transonic flutter will also be considered. For further developing the concept as a transport aircraft, future work will include considerations toward high-speed bu↵et and low-speed performance. Other future work will investigate the advantages of the transonic strut-braced-wing configuration for the single-aisle class of aircraft.
As a final note, it may be worth considering the potential impact of interference drag from the engine nacelles interacting with the strut surfaces. Although such an e↵ect may be avoidable for larger aircraft where there is su cient vertical distance toward the wing and strut roots to provide clearance, this may not be the case for regional jets with relatively large diameter turbofan engines. In these instances, it is recommended that this e↵ect be accounted for in a future work.