Three-dimensional kinematics of hummingbird flight

doi:10.1242/jeb.005686

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First published online June 15, 2007
Journal of Experimental Biology 210, 2368-2382 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.005686

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Three-dimensional kinematics of hummingbird flight

Bret W. Tobalske¹^,*, Douglas R. Warrick², Christopher J. Clark³, Donald R. Powers⁴, Tyson L. Hedrick⁵, Gabriel A. Hyder¹ and Andrew A. Biewener⁶

¹ Department of Biology, University of Portland, 5000 N. Willamette Boulevard, Portland, OR 97203, USA
² Department of Zoology, Oregon State University, 2002 Cordley Hall, Corvallis, OR 97331, USA
³ Department of Integrative Biology, University of California, Berkeley, 3060 Valley Life Sciences Building # 3140, Berkeley, CA 94720, USA
⁴ Biology Department, George Fox University, 414 N. Meridian Street, Newberg, OR 97132, USA
⁵ Department of Biology, University of North Carolina, Chapel Hill, NC 27599 USA
⁶ Concord Field Station, Department of Organismic and Evolutionary Biology, Harvard University, Old Causeway Road, Bedford, MA 01730, USA

^* Author for correspondence (e-mail: tobalske{at}up.edu)

Accepted 24 April 2007

Summary

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

Hummingbirds are specialized for hovering flight, and substantialresearch has explored this behavior. Forward flight is alsoimportant to hummingbirds, but the manner in which they performforward flight is not well documented. Previous research suggeststhat hummingbirds increase flight velocity by simultaneouslytilting their body angle and stroke-plane angle of the wings, withoutvarying wingbeat frequency and upstroke: downstroke span ratio.We hypothesized that other wing kinematics besides stroke-planeangle would vary in hummingbirds. To test this, we used synchronizedhigh-speed (500 Hz) video cameras and measured the three-dimensionalwing and body kinematics of rufous hummingbirds (Selasphorusrufus, 3 g, N=5) as they flew at velocities of 0-12 m s^-1 ina wind tunnel. Consistent with earlier research, the anglesof the body and the stroke plane changed with velocity, andthe effect of velocity on wingbeat frequency was not significant.However, hummingbirds significantly altered other wing kinematicsincluding chord angle, angle of attack, anatomical stroke-planeangle relative to their body, percent of wingbeat in downstroke,wingbeat amplitude, angular velocity of the wing, wingspan atmid-downstroke, and span ratio of the wingtips and wrists. Thisvariation in bird-centered kinematics led to significant effectsof flight velocity on the angle of attack of the wing and thearea and angles of the global stroke planes during downstrokeand upstroke. We provide new evidence that the paths of thewingtips and wrists change gradually but consistently with velocity,as in other bird species that possess pointed wings. Althoughhummingbirds flex their wings slightly at the wrist during upstroke,their average wingtip-span ratio of 93% revealed that they have kinematically`rigid' wings compared with other avian species.

Key words: Rufous hummingbird, Selasphorus rufus, kinematics, flight

Introduction

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

Hummingbirds (Trochilidae) are best known for their sustainedhovering abilities, but they also regularly use forward flight.Both types of flight are central to the ecology of hummingbirds.While they routinely hover during foraging and displaying (Greenewalt, 1960a;Wells, 1993; Stiles, 1982; Altshuler and Dudley, 2002), theymust also fly between foraging locations, at which time theirvelocities range from 5 to 11 m s^-1 (Gill, 1985). Laboratorytests have shown that they are capable of even greater forwardvelocities, exceeding 13 m s^-1 (Greenewalt, 1960a; Chai andDudley, 1999; Chai et al., 1999). Some species migrate longdistances; the total migration distance for the rufous hummingbird(Selasphorus rufus) may exceed 6000 km, and the ruby-throatedhummingbird Archilocus colubris migrates, non-stop, over theGulf of Mexico (Calder, 1993; Robinson et al., 1996).

Many aspects of hovering have been studied in hummingbirds,including kinematics (Stolpe and Zimmer, 1939; Greenewalt, 1960a;Greenewalt, 1960b; Weis-Fogh, 1973), physiology (Weis-Fogh, 1972;Epting, 1980; Bartholomew and Lighton, 1986; Wells, 1993; Chaiand Dudley, 1996) and aerodynamics (Warrick et al., 2005). Indeed,hummingbirds have emerged as a model assemblage for investigatingmaximal power capacity during hovering and climbing flight throughthe use of hypoxic, hypobaric and load-lifting protocols (Chaiand Dudley, 1995; Chai and Dudley, 1999; Chai and Millard, 1997; Chaiet al., 1999; Altshuler and Dudley, 2002; Altshuler et al.,2004). A prominent feature of wing motion during hovering inhummingbirds is pronounced supination about the long axis ofthe wing during upstroke, which is associated with a `figure-8' pathof the wingtip in lateral projection (Stolpe and Zimmer, 1939; Greenewalt,1960a). It was formerly thought that hovering downstroke andupstroke were kinematically and aerodynamically symmetrical,with each supporting body weight equally over each half of thewingbeat cycle (Stolpe and Zimmer, 1939; Greenewalt, 1960a;Greenewalt, 1960b; Weis-Fogh, 1972; Weis-Fogh, 1973).

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Fig. 8. Kinematic variables derived using free-stream velocity (V) and induced velocity (V_i) for rufous hummingbirds (Selasphorus rufus, N=5) flying at velocities of 0-12 m s^-1. (A) Global stroke-plane area for downstroke and upstroke. (B) Global stroke-plane angle for downstroke ( ${Psi}$ _d) and upstroke ( ${Psi}$ _u). (C) Angle of attack of the wing ( ${alpha}$ ) at mid-downstroke and mid-upstroke.

This assumption of symmetry between half strokes needs to berevisited with new data, particularly because the aerodynamicsof hovering are likely to be unsteady and, therefore, challengingto predict from kinematics (Spedding, 1993

, Dickinson et al.,1999

). Kinematics of similarly sized hovering hawkmoths Manducasexta (Willmott and Ellington, 1997b

) lead to an estimate thatthe upstroke produces more lift than downstroke, while flowvisualization about a dynamically scaled model indicates thedownstroke produces more lift due, in part, to leading-edge vorticity(Van den Berg and Ellington, 1997

; Willmott et al., 1997

). Forthe hovering hummingbird, the camber of the wing is differentduring the two halves of the wingbeat, and wake measurements indicatethe majority (75%) of the weight support is provided by downstroke, whileupstroke supports 25% (Warrick et al., 2005

In contrast with the wealth of data available on hovering performancein hummingbirds, relatively little is known about how hummingbirdsaccomplish forward flight (Altshuler and Dudley, 2002). Greenewalt(Greenewalt, 1960a) presents lateral-view illustrations of wingpaths and body postures of ruby-throated hummingbirds flyingat 0, 4 and 13 m s^-1 along with brief descriptions of wing kinematicsat these velocities that include wingbeat frequency, downstrokefraction of the wingbeat cycle, and advance ratio. Data on long-axisrotation of the wing (pronation or supination) are lacking.Recent studies report maximum forward-flight velocities butnot the associated wing kinematics (Chai et al., 1999; Chaiand Dudley, 1999). From Greenwalt's description (Greenwalt,1960a), it would appear that hummingbirds vary flight velocityprimarily by changing the angle of their body relative to horizontal(ß), thereby effecting a change in stroke-plane angle,as well as potentially varying their wingbeat amplitude ( ${phi}$ ),which is known to vary according to power demands during hovering (Altshulerand Dudley, 2002; Altshuler and Dudley, 2003). Lateral-viewfigures representing the path of the wingtip hint (assumingthe birds are drawn to the same scale) that ${phi}$ may be less duringforward flight at intermediate velocity compared with duringhovering or fast flight (Greenewalt, 1960a). Paths of the wingin lateral projection also change from a figure-8 shape to anellipse as hummingbirds change from hovering to forward flight (Greenewalt,1960a).

No significant variation is reported for wingbeat frequency(f), the relative duration of the downstroke, or wing length(l) within the wingbeat cycle (Greenewalt, 1960a; Greenewalt, 1960b).Constant l would mean that upstroke:downstroke span ratio wouldbe 100%, at all flight velocities, and this has important implicationsfor the aerodynamics of flapping flight. Most birds in forward flightdecrease their span ratio using wing flexion during upstroketo avoid producing negative thrust that is of equal magnitudeto the positive thrust that they produced during downstroke (Rayner,1986; Rayner, 1988; Tobalske, 2000). Assuming hummingbirds donot flex their wings and reduce their span during upstroke, theymust change other parameters such as angular velocity or angleof attack of the wing to reduce upstroke circulation and liftso that they can sustain forward flight. Variation in circulationabout the wings would lead to the shedding of a ladder-likewake structure with `rungs' of cross-stream starting and stoppingvortices into the wake and inflation of induced drag relativeto a constant-circulation wake (Rayner, 1986). Recent kinematicevidence suggests that angle of attack and circulation variesthroughout the wingbeat cycle in cockatiels Nymphicus hollandicus(Hedrick et al., 2002), and studies of wake structure revealthat regular shedding of cross-stream vortices is a characteristicof fast flight in passerines (Spedding et al., 2003; Hedenströmet al., 2006).

Advances in technology since Greenewalt's pioneering research (Greenewalt,1960a; Greenewalt, 1960b) allow us to explore more fully howkinematics of the wings and body of hummingbirds might varywith flight velocity. Given that, even during hovering, hummingbird flightis more consistent with the flight of other birds than previously believed(Warrick et al., 2005), we predicted that hummingbirds wouldvary aspects of their wing kinematics in a manner similar toother bird species (Brown, 1953; Brown, 1963; Tobalske and Dial,1996; Tobalske, 2000; Park et al., 2001; Hedrick et al., 2002; Tobalskeet al., 2003a; Tobalske et al., 2003b; Rosén et al., 2004).

Materials and methods

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

Birds and wind tunnel
Five female rufous hummingbirds Selasphorus rufus Gmelen 1788 (bodymass 3.4 g, Table 1) were captured from the wild under permitsfrom the US Fish and Wildlife Service and Oregon Departmentof Fish and Wildlife. All housing and experimental protocols wereapproved by the University of Portland Institutional AnimalCare and Use Committee. During captivity, birds were housedin 1 mx1 mx1 m flight cages with ad libitum access to food andwater in the form of Nektar-Plus (NEKTON®; Günter Enderle,Pforzheim, Baden-Württemberg, Germany) or a 20% sucrosesolution.

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Table 1. Morphological data for the rufous hummingbird (Selasphorus rufus)

We measured the morphology of the birds with their wings spreadas in mid-downstroke using standard techniques (Tobalske etal., 1999) (Table 1). Linear measurements (mm) were obtainedusing digital calipers and metric rulers. Areas (mm²) were measuredfrom digital images using a known pixel-to-metric conversion.Average wing chord (mm) was calculated as wing area dividedby wingspan. Aspect ratio (dimensionless) was calculated as wingspandivided by wing chord. Disc loading (N m^-2) was computed asbody weight divided by disc area (S_d). For this instance, weassumed S_d= ${pi}$ (b/2)², with b=wing span. Wing loading (N m^-2) wascomputed using body weight (N) divided by combined wing area,including the projected surface area of the body between thewings.

Our wind tunnel was designed for studies of avian flight atthe University of Portland (Tobalske et al., 2005a). The tunnelis an open circuit with a closed jet, featuring a 6:1 contractionratio and a total length of 6.1 m. The working section in whichthe bird flies is square in cross-section, 60 cmx60 cmx85 cm innerdiameter at the inlet, with clear lexan walls, 6-mm thick, usedto provide views inside the working section. The flight chamberincreases to a 61.5 cmx61.5 cm outlet to accommodate boundary-layerthickening. Air is drawn through the tunnel using 7.5 kW (10horsepower) direct current motor and a 0.75 m diameter fan assembly(AFS-75 Series, SMJ Incorporated, Grand Junction, CO, USA).Velocity (V) is selected as equivalent air velocity rather thantrue air velocity (Pennycuick et al., 1997; Hedrick et al.,2002). With a protective screen of vertical wires in place atthe inlet of the working section, maximum deviations in velocitywithin a cross section are <10% of the mean, the boundarylayer is <1 cm thick, and turbulence is 1.2% (Tobalske etal., 2005a).

Birds were acclimated to the flight chamber of the wind tunnelusing an interval of 2-3 h, during which the birds were in stillair with free access to a feeder and a perch. After this acclimation,the birds would sustain flight for 1 h or longer during hovering(0 m s^-1) and 2 m s^-1 and 10 min or longer during forward flightat faster velocities (4-12 m s^-1).

We allowed the birds to rest on the perch between trials, andwe controlled access to the feeder to motivate flight. As thefeeder was used in all trials, it undoubtedly affected inflowon the bird. Therefore, caution is warranted when extrapolatingfrom our results to estimate performance in free flight. Thefeeder was a modified 1 ml Tuberculin syringe, 6.6 mm in diameter,with tabs removed and tip opening enlarged and painted red usingfingernail polish. It was aligned parallel with inflow and suspendedfrom the ceiling of the flight chamber using a steel wire (1.5mm in diameter). The tip of the feeder was located in the midlineof the flight chamber, approximately 10 cm back from the inletand 20 cm down from the ceiling. Between trials, the feederwas manually refilled as necessary using Nektar-Plus or 20%sucrose. The perch was constructed of a 15 cm length of steelwire, 1.5 mm in diameter, and supported 20 cm up from the floorof the flight chamber between steel supports (12 mmx12 mm incross section). The perch was oriented perpendicular to inflow,and at a minimum distance of 50 cm behind the tip of the feeder.

The combined frontal area of the feeder and perch ( $~$ 0.008 m²)was only 2% of the 0.36 m² area of the inlet of the flight chamber,so it was not necessary to correct tunnel velocity for blockingeffects (Barlow et al., 1999).

Kinematics
We measured wing and body movement using digital video and three-dimensional(3D) reconstruction (Warrick and Dial, 1998; Hedrick et al.,2002). Digital video recordings, 2-4 s in duration, were obtainedduring longer intervals of sustained flight. We used two synchronizedRedlake cameras, a PCI-2000 and PCI-500 (Redlake MASD LLC, SanDiego, CA, USA) sampling at 500 frames s^-1 and with a shutterspeed of 1/2500 s. Images were stored to computer using PCI-Rv.2.18 software. Flights were illuminated using four 650-W halogenlights (Lowel Tota-light, Lowel-Light Manufacturing, Inc., Brooklyn,NY, USA) distributed around the outside of the flight chamber.

We digitized anatomical landmarks and accomplished 3D reconstructionusing custom M-files (available: http://www.unc.edu/~thedrick/) inMATLAB v.6.5 and v.7.0 (The Mathworks, Inc., Natick, MA, USA).To identify anatomical landmarks for digitizing, we marked thebirds prior to the experiments using 1.5-mm dots of non-toxicwhite paint on the feathers over the spine (approximately over1st thoracic vertebrae), dorsal and right-lateral base of tail,and, on the right wing: shoulder, wrist, distal tip of 1st secondaryand distal tip of 9th primary.

For 3D reconstruction, we merged two-dimensional (2D) coordinatesfrom each camera plane into a single 3D space using the DirectLinear Transform coefficients derived from a sixteen-point calibrationframe (Hatze, 1988). For digitized points on all birds, medianRMS error was <1 mm. Occasionally a point was not in theview of both cameras, resulting in a gap in the reconstructedpoint sequence. Point interpolation and filtering were accomplishedusing a quintic spline fit to known RMS error using the GeneralizedCross Validatory/Spline program (Woltring, 1986).

Subsequent kinematic analysis used 3D coordinates of anatomicallandmarks and software including MATLAB, IGOR Pro. (v.4.061,Wavemetrics, Inc., Beaverton, OR, USA) and Excel (v.2003, MicrosoftCorp, Renton, WA, USA). We utilized a bird-centered coordinatesystem (x, y and z axes centered at shoulder) to measure kinematicsrelative to the body and a global-coordinate system to measureaerodynamically relevant kinematics (Gatesy and Baier, 2005; Rosénet al., 2004) that require an estimate of translation of thebody due to flight velocity. We accomplished transitions betweencoordinate systems using translation along x, y and z axes androtation about Euler angles that described body pitch aboutthe y axis and yaw about the z axis. The anatomical landmarkswe used did not permit measurement of roll, so we assumed thatno roll was present and visually inspected video samples to eliminatefrom analysis any intervals of flight in which the birds appearedto maneuver. Thus, the observed lateral midline of the body (Fig. 1A),between the shoulder and the base of the tail, represented themid-frontal plane, and the dorsal mid-line of the body, betweenthe spine and the base of the tail, represented the mid-sagittalplane.

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Fig. 1. Angles and areas measured from wing and body motion of rufous hummingbirds (Selasphorus rufus) during flight. Certain measures were bird-centered (A) and those in (B,C) were derived from global coordinates because they incorporated free-stream velocity. Filled-outlines of bird (A,B) illustrate wing at the start of downstroke, and broken-outline of wing illustrates wing position at the end of downstroke. (A) Black cross-section represents a pronated wing at mid-downstroke. ${alpha}$ _c=chord angle relative to mid-frontal plane of body with ${alpha}$ _c>0 for supination and ${alpha}$ _c<0 for pronation. ß=body angle relative to horizontal. ${gamma}$ _b=anatomical stroke-plane angle relative to mid-frontal plane of body. ${gamma}$ _h=tracking stroke-plane angle relative to horizontal. (B) ${Psi}$ _d and ${Psi}$ _u=global stroke-plane angle during downstroke and upstroke, respectively. (C) Global stroke-plane area was outlined by the wingtips during downstroke (dark gray areas) and upstroke (light gray areas) for each wingbeat.

Movement at the wrist was used to identify characteristic portionsof wingbeats including the transitions between upstroke anddownstroke and the middle of upstroke and downstroke. At thestart of each half-stroke, wrist span began increasing (thewrists were abducted from the mid-sagittal plane of the body).Downstroke started with wrist depression and upstroke beganwith wrist elevation. Mid-half-strokes occurred as the wristspanwas at a local maximum, and with wrist elevation at the mid-frontalplane of the body. Body angle (ß, deg.) was the acuteangle between horizontal and the mid-frontal plane of the body(Fig. 1A). The stroke plane of the wing connected the shoulder,wingtip at start of downstroke and wingtip at the end of downstroke.We measured `anatomical' stroke-plane angle (Gatesy and Baier,2005

) relative to the mid-frontal plane of the body ( ${gamma}$ _b, deg.)and a `tracking' stroke plane angle relative to the horizontalplane ( ${gamma}$ _h, deg.). Wing chord was a line connecting the wristand the distal tip of the 1st secondary, and chord angle ( ${alpha}$ _c,deg.) was the cranially oriented acute angle formed betweenthis lead line and the mid-frontal plane of the bird. This anglewas <0° for pronation and >0° for supination.

We calculated wing and wrist span (mm) as double the perpendiculardistance between the line connecting the spine and dorsal baseof tail (hereafter `dorsal midline') and the distal tip of the9th primary or the wrist, respectively. Span ratios for thewingtips and wrists (dimensionless) were spans at mid-upstrokedivided by spans at mid-downstroke.

The inverse of the duration of the wingbeat gave wingbeat frequency (f,Hz). Wingbeat amplitude ( ${phi}$ , deg.) was measured in the bird-centeredcoordinate system as the acute angle formed between the line connectingthe shoulder and wingtip at the start of downstroke and theline connecting the shoulder and the distal wingtip at the endof downstroke. Duration (s) of downstroke and upstroke wereused to compute the proportion of time spent in downstroke (%).Average angular velocity of the wing (rad s^-1) was ${phi}$ dividedby duration of each downstroke or upstroke.

Free-stream velocity (V) in the wind tunnel and an estimateof the vertical component of induced velocity (V_i) were incorporatedinto certain kinematic measurements. Angle of attack of thewing ( ${alpha}$ , deg.) was the angle between wing chord and resultantvelocity summed from wing-flapping velocity, free-stream airvelocity in the wind tunnel, and V_i. The 3D flow field in thevicinity of the wings and body of a hummingbird is complex (Warrick etal., 2005) and a reasonable estimate of instantaneous near-fieldflow (Sane, 2006) was beyond the scope of the present study.As a simple first approximation, we calculated V_i using Rankine-Froudemomentum-jet theory, treating the wings as an actuator disc (Pennycuick,1975). For hovering:

Formula 1 (1)
and,for forward flight:

Formula 2 (2)
whereM_b=body mass, g=gravitational acceleration, ${rho}$ =air density, whichaveraged 1.15 kg m^-3 during the experiments, and S_d was measuredas the horizontal projection of the bird-centered stroke planearea (Wakeling and Ellington, 1997):

Formula 3 (3)
where l=wing length. We translated bird-centeredcoordinates along the x axis, according to flight velocity andtime (Fig. 1B,C), so that we could measure `global' angle betweenthe stroke-plane and horizontal for downstroke ( ${Psi}$ _d) and upstroke( ${Psi}$ _u) and `global' stroke-plane area (mm²) outlined by the wingtipsduring each half stroke.

Statistical analyses
For each kinematic variable, we computed the mean value withineach bird (N=5-10 wingbeats) for each velocity (N=7). We thenused these means to test for a significant effect of flightvelocity upon each variable using a univariate repeated-measuresANOVA (d.f. 4, 6) and StatView v.5.0.1 (SAS Institute, Inc.,Cary, NC, USA). We also computed an overall mean ± s.d.among the 7 flight velocities.

To describe variation in ${alpha}$ _c and ${alpha}$ within wingbeats, we convertedtime within a wingbeat cycle into a percentage of the full cycle thatbegan with the start of downstroke and ended with the startof the subsequent downstroke. We then interpolated observed ${alpha}$ _c and ${alpha}$ using cubic-spline fitting with 100 points per curve.We computed an average and s.d. among birds for each of the100 points.

Values are presented as means ± s.d.

Results

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

Hummingbirds accomplished flight at different velocities bysignificantly varying the majority (75%) of the bird-centeredkinematics variables that we measured (Table 2, Fig. 2).

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Table 2. Variation in bird-centered kinematics among flight velocities (0–12 m s^-1) in the rufous hummingbird (Selasphorus rufus)

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Fig. 2. Wing motion relative to the body of a rufous hummingbird (Selasphorus rufus) flying at velocities of 0-12 m s^-1. (A) Dorsal view with bird silhouette at mid-downstroke. As we measured kinematics only from the right wing, paths for the left-wing are mirror images. (B) Lateral view with bird silhouette at start of downstroke. Black circles indicate position of wingtips, and white circles indicate position of wrists. Paths of wing motion are from 3D measurements, so circles within the paths are synchronized for a given velocity. Circles and arrows indicate sequential position and local direction of movement.

Dorsal and lateral projections of the paths of the wingtipsand wrists revealed gradual changes across the range of velocities (Fig. 2).During upstroke of slow flight (0 and 2 m s^-1), the tips andwrists traced in reverse nearly the same paths that were exhibitedduring downstroke. Lateral views of the paths at these slowflight velocities reveal an upwardly concave path of the wristsand wingtips, with the path of the wingtips also describinga horizontal figure-8 pattern in which the tip was higher duringearly downstroke, dipped down during late downstroke, raisedat the start of upstroke, and dipped low during mid- and lateupstroke. Wing movement at flight velocities of 4-12 m s^-1 createdtwo patterns. In dorsal view, the path of the wrists, but especially thewingtips, described a figure-8 loop with maximal wing span alwaysexhibited during the middle of downstroke, and with the figure-8loops becoming progressively more obvious as velocity increased.In lateral view, the paths of the wrists and wingtips were ellipses,with the wrists and wingtips positioned more cranially duringdownstroke and more caudally during upstroke.

As flight velocity increased from 0 to 12 m s^-1, body angle (ß)decreased from 50±2° to 13±5° and tracking stroke-planeangle ( ${gamma}$ _h) increased from 15±4° to 68±5°(Fig. 3A). These changes in ß and ${gamma}$ _h produced a minimumanatomical stroke-plane angle ( ${gamma}$ _b) of 61±5° duringflight at 6 m s^-1 and a maximum ${gamma}$ _b of 82±3° duringflight at 12 m s^-1.

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Fig. 3. Angles describing bird-centered wing and body kinematics in rufous hummingbirds (Selasphorus rufus, N=5) flying at velocities 0-12 m s^-1. (A) Body angle relative to horizontal (ß), tracking stroke-plane angle relative to horizontal ( ${gamma}$ _h) and anatomical stroke-plane angle relative to mid-frontal plane of body ( ${gamma}$ _b). (B) Chord angle of wing relative to mid-frontal plane of body ( ${alpha}$ _c) at mid-downstroke and mid-upstroke. Values are means ± s.d.

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Fig. 4. Variation in chord angle relative to mid-frontal plane of body ( ${alpha}$ _c) during wingbeats in rufous hummingbird (Selasphorus rufus, N=5) flying at velocities of 0-12 m s^-1. Wingbeat duration is expressed as a percentage of the entire wingbeat. The broken line indicates wrist elevation relative to mid-frontal plane, and the shaded area represents downstroke. Values are means ± s.d.

Chord angle ( ${alpha}$ _c) varied significantly among flight velocities,with P=0.0168 for ${alpha}$ _c at mid-downstroke and P<0.0001 for ${alpha}$ _cat mid-upstroke (Table 2, Fig. 3B). Pronation of the wing, relativeto the mid-frontal plane, of the body, occurred through mostof downstroke. Consequently, ${alpha}$ _c was negative during the majority ofthis phase of the wingbeat. Regardless of flight velocity, atthe start of downstroke, ${alpha}$ _c was near 0°, reached a minimumof between -13±17° and -36±5° at mid-downstroke,and returned to 0° at approximately 40% of the wingbeatcycle, 10% of the cycle duration before the onset of upstroke(Fig. 4). In contrast with downstroke, the wing was supinatedduring most of upstroke, resulting in positive values of ${alpha}$ _c.Peak positive values of ${alpha}$ _c were exhibited at mid-upstroke, ata time 65-70% into the full wingbeat cycle. Mid-upstroke ${alpha}$ _c decreasedwith increasing flight velocity from a maximum of 93±4° duringhovering (0 m s^-1) to 26±10° and 26±8° duringflight at 10 and 12 m s^-1.

Interactions among frequency (f), amplitude ( ${phi}$ ), and the percentageof the wingbeat cycle spent in downstroke produced significant variationin the angular velocity of the wing among flight velocities (Fig. 5).With an average of 41±1 Hz, f was among the minorityof bird-centered kinematics that did not vary significantlywith flight velocity (P=0.1668). Wingbeat amplitude ( ${phi}$ ) variedaccording to a U-shaped curve, with ${phi}$ between 100±6 and103±19° at velocities of 2-8 m s^-1 and ${phi}$ from 109±12to 126±12° at 0, 10 and 12 m s^-1. The percentageof the wingbeat spent in downstroke increased with increasingflight velocity from 48% at 0 and 2 m s^-1 to 53±1% at12 m s^-1. For both downstroke and upstroke, the angular velocityof the wing varied with velocity according to U-shaped curves.Average angular velocity among all flight velocities was similar betweendownstroke (155+16 rad s^-1) and upstroke (156+19 rad s^-1). Localminima and maxima for each half of the wingbeat cycle occurredat different velocities. Specifically, angular velocity during downstrokevaried from 140±6 rad s^-1 at 8 m s^-1 to 178±21rad s^-1 at 0 m s^-1, while minimum angular velocity during upstrokewas 134±24 rad s^-1 at 4 m s^-1 and maximum was 195±23rad s^-1 at 12 m s^-1.

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Fig. 5. (A) Wingbeat frequency and amplitude ( ${phi}$ ), (B) proportion of wingbeat spent in downstroke and (C) average angular velocity of the wing, during downstroke and upstroke during flight in rufous hummingbirds (Selasphorus rufus, N=5) flying at velocities of 0-12 m s^-1. Values are means ± s.d.

All variables related to wing and wrist spans exhibited relativelylow variability among flight velocities (Table 2); nevertheless,velocity had a significant effect upon wingspan at mid-downstroke(P=0.0014) and the span ratios of the wingtips (P=0.0072) andwrists (P=0.0332). At mid-downstroke, wingspan was slightlyless during flight at 0 and 2 m s^-1 (93±3 mm and 95±5mm, respectively) compared with flight at velocities of 4-12m s^-1, where mid-downstroke spans were between 100±3mm and 102±4 mm. In general, span ratio for the wingtips andthe wrists decreased as flight velocity increased. A minor deviationfrom this overall pattern was an observed increase in averagespan ratio of the wrist from 98±2 to 99±1% between4 and 6 m s^-1. Among flight velocities, span ratio for the wristswas greater (98±1%) than for the wingtips (93±3%).

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Fig. 6. (A) Wingspan and wristspan during mid-downstroke (black circles) and mid-upstroke (white circles) and (B) span ratio in rufous hummingbirds (Selasphorus rufus, N=5) flying at velocities of 0-12 m s^-1. Values are means ± s.d.

All of the measured global-coordinate wing kinematics variedsignificantly with flight velocity (Table 3; Figs 7, 8, 9).Dorsal and lateral projections of the paths of the wingtipsand wrists revealed that overlap in wrist and tip excursionoccurred between subsequent downstrokes at 0 and 2 m s^-1, andoverlap in the paths of the wingtips was also apparent at 4m s^-1. At each flight velocity, downstroke covered a largerarea than upstroke. However, the difference between the meanswas less than 1 s.d. during hovering and was accounted for solelyby slight flexion of the wings during upstroke, with span ratioof 98±4% (Fig. 6B). Downstroke plane area increased uniformlywith velocity from 3059±411 mm² at 0 m s^-1 to 15296±1370mm² at 12 m s^-1. Upstroke-plane area was 2830±380 mm²during hovering, approximately 4700 mm² during flight at 2-4m s^-1, and increased with increasing velocity to reach a maximumof 10011±278 mm² during flight at 12 m s^-1.

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Table 3. Variation in global-coordinate wing kinematics among flight velocities (0–12 m s^-1) in the rufous hummingbird (Selasphorus rufus)

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Fig. 7. Dorsal and lateral views of wingtip and wrist paths with translation due to free-stream velocity (V) and time. These data are from a rufous hummingbird (Selasphorus rufus) flying at velocities of 0-12 m s^-1 (same subject as in Fig. 2). All x-axes represent 500 mm along a flight path. Solid line=wingtip, dotted line=wrist. Shaded regions indicate downstroke as defined using wrist motion. For each downstroke, wingtip excursion exceeded wrist excursion in all dimensions, so the shaded regions would be enlarged if downstroke were based on motion of the wingtip.

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Fig. 9. Variation in angle of attack ( ${alpha}$ ) within wingbeats in rufous hummingbirds (Selasphorus rufus, N=5) flying at velocities of 0-12 m s^-1. Wingbeat duration is expressed as a percentage of the entire wingbeat. The broken line indicates wrist elevation relative to mid-frontal plane of body, and the shaded area indicates downstroke. Values are means ± s.d.

Along with changes in stroke plane area (Fig. 7 and Fig. 8A),the angle of the aerodynamic stroke plane changed with velocity (Fig. 7and Fig. 8B). A slight increase in ${Psi}$ _d occurred as velocity increased,with a mimimum of 14±4° during flight at 2 m s^-1increasing to 23° during flight from 8 to 12 m s^-1. In dramaticcontrast, ${Psi}$ _u decreased with each incremental increase in velocity,from 162±4° during hovering to 35±3° duringflight at 12 m s^-1.

Angle of attack ( ${alpha}$ ) varied among velocities and within wingbeats (Table 3; Fig. 8Cand Fig. 9). Mid-downstroke ${alpha}$ was greatest during hovering (23±5°),decreased with increasing velocity, and varied from 11-13°during faster flight (6-12 m s^-1). During mid-upstroke of flightat 0 and 2 m s^-1, ${alpha}$ was negative, indicating an inverted airfoil(i.e. with the curved, anatomical underside of the wing facingin the same direction as presumed low pressure above the wing),whereas ${alpha}$ was positive at mid-upstroke during flight from 4 to12 m s^-1. Negative values for mid-upstroke ${alpha}$ produced an overallmean among flight velocities (9±22°) that was atypicalof any given velocity. Ignoring which surface of the wing was uppermost,| ${alpha}$ | was more useful as an average descriptor of the relativedirection of incurrent air; mid-upstroke | ${alpha}$ | averaged 22±4°.Average ${alpha}$ at mid-downstroke 14±1°.

Within wingbeats, ${alpha}$ varied more during slow flight (0 and 2 m s^-1)compared with flight at 4-12 m s^-1 (Fig. 9). For example, ${alpha}$ rangedfrom -32±14° to 56±7° during flight at0 m s^-1, and from 11±4° to 33±11° duringflight at 12 m s^-1. During hovering, ${alpha}$ varied between downstrokeand upstroke approximately in a symmetrical manner about 0°.At the middle of each half stroke, | ${alpha}$ | was 22-23°. Negative ${alpha}$ was exhibited from slightly before the end of downstroke (44%of wingbeat cycle) to slightly before the end of upstroke (93%of cycle). The interval of negative ${alpha}$ was more contracted induration at 2 m s^-1 and occurred during the middle of upstroke,between times at 62% and 87% of the full cycle. Peak positive ${alpha}$ was exhibited during early downstroke of flight at 0 m s^-1,9% into the wingbeat cycle. In contrast, for all other flightvelocities, peak positive ${alpha}$ was exhibited at 51-58% of the wingbeatcycle, concurrent with, or slightly after, the transition between downstrokeand upstroke.

Discussion

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

Our experiments revealed that hummingbirds change a varietyof bird-centered kinematic parameters among flight velocitiesand within wingbeats (Table 2, Figs 2, 3, 4, 5, 6), which causeschanges in global-coordinate variables that are likely relevantto their aerodynamic performance (Table 3; Figs 7, 8, 9). Thus,our experiments provide new details about wing kinematics thatshould help improve understanding of hummingbird flight.

Three of the patterns that we observed were consistent withthe kinematics previously reported for ruby-throated hummingbirds (Greenewalt,1960a; Greenewalt, 1960b): f did not vary significantly amongflight velocities (Table 2, Fig. 5A), while ß and ${gamma}$ _hexhibited significant variation. The lack of variation in famong flight speeds is also consistent with hummingbird behavior duringhovering. When adjusting to varying power demands of load liftingor hovering in hypodense air, hummingbirds modulate ${phi}$ to a muchgreater degree than f (Chai and Dudley, 1995; Chai et al., 1997;Chai and Millard, 1997; Altshuler and Dudley, 2002; Altshulerand Dudley, 2003).

A mechanical oscillator hypothesis has been proposed for modeling hummingbirdwing motion (Greenewalt, 1960a; Greenewalt, 1960b). This describesthe wing as a damped, driven oscillator, and one predictionfrom the model is that fl^5/4is constant. Among flight velocitiesstudied here, this product did not vary significantly usingf and mid-downstroke l (F=1.779, P=0.1461, d.f. 4, 6), or usingf and mid-upstroke l (F=0.888, P=0.5188, d.f. 4, 6). Thus, ourresults provide support for the hypothesis, and demonstratehow hummingbirds modulate the orientation and trajectory oftheir mechanical oscillator to accomplish a change in velocity.Additional tests of the assumptions of the hypothesis are necessary,however, including the contribution of profile drag to dampingand whether muscle force is proportional to strain (Greenewalt, 1960b).

Insight into muscle force production is also necessary to evaluatewhether the U-shaped curve exhibited for angular velocity ofthe wing (Fig. 5C) is representative of the shape of the mechanicalpower curve for hummingbird flight. If muscle force is proportionalto strain, as assumed by the mechanical oscillator hypothesis(Greenwalt, 1960b), and strain in the primary flight musclesis proportional to ${phi}$ (Fig. 5A), our kinematic data indicate thatthe mechanical-power curve for hummingbird flight has a pronouncedU-shape, similar to curves exhibited by other bird species (Tobalskeet al., 2003a).

The general pattern of bird-centered wingtip paths in lateralprojection (Fig. 2B) was similar to that reported for ruby-throatedhummingbirds (Greenewalt, 1960a), but our data furnish new insightinto lateral-projections of wrist motion as well as the pathfollowed by the tips and wrists in dorsal projection (Fig. 2A).Changing velocity of flight in the wind tunnel in 2 m s^-1 incrementsresulted in gradual but consistent shifts in wingtip and wristpaths. The figure-8 path of the tips that was apparent in lateralview at 0 and 2 m s^-1, and, to a lesser extent, during flightat 4 m s^-1, is similar to that exhibited during slow flightby other bird species that possess pointed wings or wings ofrelatively high aspect ratio (AR=5.5-7), including the rockdove (Columba livia, hereafter `pigeon') and cockatiel (Brown,1953; Brown, 1963; Scholey, 1983; Tobalske and Dial, 1996; Tobalske,2000; Tobalske et al., 2003a). Hummingbirds also share withpigeons characteristics of wing motion apparent in faster flight,specifically with the tips and wrists following an ellipticaltrajectory in lateral view and a figure-8 trajectory in dorsal view(Tobalske and Dial, 1996) (Fig. 2B).

The wing paths that hummingbirds share with other, distantlyrelated species highlights that the evolution and functionalsignificance of the wingtip-reversal upstroke used by otherspecies merits additional study. Flow visualization shows thatthe upstroke in hovering hummingbirds, featuring negative angleof attack and chord angle ( ${alpha}$ and ${alpha}$ _c; Figs 3, 4, 5), provides 25%of the weight support required from a full wingbeat cycle (Warricket al., 2005). In comparison, some studies suggest that thetip-reversal upstroke of other bird species is an aerodynamicallyinactive recovery stroke (Spedding et al., 1984; Hedrick etal., 2004), while others indicate that the proximal wing maycontinue to support body weight while the distal wing providesthrust (Corning and Biewener, 1998; Usherwood et al., 2003; Usherwoodet al., 2005). An extended, tip-reversed wing may also facilitatemaneuvering at low speeds (Warrick and Dial, 1998). At present,the relationship between tip reversal and the phylogeny of birdsis unknown, but it is possible that a tip-reversal upstrokemay represent a precursor style of wing movement that an ancestralform exhibited early during the evolution of hovering withinthe Trochilidae.

Our measurements of ${alpha}$ _c indicated continuous variation within(Fig. 4) and among (Table 2, Fig. 3B) flight velocities. Contraryto an expectation from earlier reports (Stolpe and Zimmer, 1939; Greenewalt,1960a; Greenewalt, 1960b) that the two halves of the hoveringwingbeat would be symmetrical, mirror images of one another,| ${alpha}$ | during upstroke and downstroke exhibited greater disparityat slow velocity (0-4 m s^-1) than during faster flight (6-12m s^-1). The only comparable values of ${alpha}$ _c are available for zebrafinch at mid-downstroke (Tobalske et al., 1999), and the coefficientof variance (CV=s.d./mean) for ${alpha}$ _c at mid-downstroke is greaterin hummingbirds (29%) than in zebra finch (17%).

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Fig. 10. Wingspan ratio as a function of flight velocity compared among bird species. Values shown are means. Colors indicate species within the same order: Red=Trochiliformes, rufous hummingbird Selasphorus rufus (this study); blue=Columbiformes, ringed turtle-dove Streptopelia risoria (Tobalske et al., 2003b

) and rock dove (`pigeon') Columba livia (Tobalske and Dial, 1996

); green=Psittaciformes, budgerigar Melopsittacus undulatus and cockatiel Nymphicus nymphicus (Tobalske et al., 2003b

); orange=Passeriformes, barn swallow Hirundo rustica (Park et al., 2001

), thrush nightingale Luscinia luscinia (Rosén et al., 2004

), black-billed magpie Pica hudsonica ¹Tobalske and Dial (Tobalske and Dial, 1996

), ²Tobalske et al. (Tobalske et al., 2003b

) and zebra finch Taeniopygia guttata (Tobalske et al., 1999

Zebra finch use an extremely different flight style comparedwith rufous hummingbirds (Tobalske et al., 1999

; Tobalske etal., 2005a

), and further comparison illustrates that the relative magnitudeof variation for a given bird-centered kinematic variable differs betweenthese two species depending upon the variable under consideration. Zebrafinch have low-aspect ratio, rounded wings (AR=4.5), regularly flextheir wings to adduct them almost against their body on upstroke(average span ratio=19%) and regularly use intermittent bounds(40-45% of total time during fast flight). Compared with zebrafinch (Tobalske et al., 1999

), hummingbirds exhibited greatervariation in the percentage of their wingbeat spent in downstroke(CV=8% vs 3%), ${gamma}$ _h (CV=48% vs 24%) and ${gamma}$ _b (CV=12% vs 4%). In contrast, variationis greater in zebra finch for f (CV=5% vs 2%), ${phi}$ (CV=15% vs 8%),ß (CV=45% vs 12%), and wingspan at mid-upstroke (CV=13%vs 2%). Angular velocity of the wing during downstroke exhibitsa CV of 11% in both species.

A comprehensive comparative analysis for all of these kinematicparameters awaits further study; however, one pattern that readilyemerges from the data available for these and other bird speciesis that hummingbirds exhibit the highest span ratio, and thelowest variation in span ratio, of any species studied to date(Fig. 10). Their wingtip span ratio averaged 93% among velocities,and span ratios in other species vary from 17% to 80% (Tobalskeand Dial, 1996; Park et al., 2001; Tobalske et al., 2003b; Rosénet al., 2004). Although this supports the view that hummingbirdshave a kinematically `rigid' wing, broadly consistent with themechanical oscillator hypothesis (Greenewalt, 1960a; Greenewalt,1960b), a span ratio of less than 100% is evidence that theyflex their wings on upstroke (Fig. 2A, Fig. 6 and Fig. 7).

Given that average wingtip span ratio in rufous hummingbirdswas less than wrist span ratio (Table 2; Fig. 6), it appearsthat the majority of wing flexion during upstroke in hummingbirdsoccurs at the wrist, rather than at the shoulder or elbow. Further,the decrease in tip span ratio with flight velocity was, inroughly equal measure, a result of increased wrist flexion duringupstroke, and increased extension during downstroke. The increasein downstroke span with increasing forward flight velocity mayhave allowed for the greater translational velocity requiredfor a useful ${alpha}$ , as the vector of incident air becomes increasinglydominated by forward flight velocity (V). The change in spanratio may also provide new insight into the functional morphologyof the muscular and skeletal elements of the hummingbird wing,which feature a proportionally short humerus and long distal (handwing) bones (Stolpe and Zimmer, 1939; Greenewalt, 1960a). Hummingbirdsalso have exaggerated curvature of their radius and ulna thatis hypothesized to accommodate proportionally large musclesto control extension, flexion and long-axis rotation of thehand wing (Dial, 1992b).

Species that are closely related to each other, hypothesizedto be within the same avian order (Sibley and Ahlquist, 1990),appear to group similarly according to their characteristic spanratios (Fig. 10). Fully testing phylogenetic influences (Felsenstein,1985; Garland et al., 1992) on this pattern relative to wingdesign is beyond the scope of our present analysis. Regardlessof aspect ratio or wing shape, there is a general trend to decrease spanratio with increasing velocity among the rufous hummingbirdsstudied here, as well as in previously studied Columbiformes(pigeons and ringed turtle doves Streptopelia risoria), Psittaciiformes(budgerigars Melopsittacus undulatus and cockatiels) and twospecies of Passeriformes [barn swallows Hirundo rustica andblack-billed magpies Pica hudsonica (Tobalske and Dial, 1996;Park et al., 2001; Tobalske et al., 2003b)]. This trend maybe explained by the need to limit negative thrust during a liftingupstroke at fast velocities (Rayner, 1986; Rayner, 1988; Tobalske,2000; Hedrick et al., 2002). Two passerine species, the zebrafinch and thrush nightingale (Luscinia luscinia), exhibit anincrease in span ratio with increasing velocity (Tobalske etal., 1999; Rosén et al., 2004). At least for the zebrafinch, we predict the increase in span ratio is due to an efforton the part of the bird to enhance weight support by movingtoward a lifting upstroke because the bird can potentially useintermittent bounds to offset an increase in average thrustrequirements as velocity increases (Tobalske et al., 1999).

Other than a report of `undulating' during flight (Murphy, 1913),there have been no published accounts of hummingbirds usingintermittent flight. Given the widespread use of this flightstyle in other species of small birds (Rayner, 1985, Tobalske,2001), it is therefore noteworthy that two of the five birdsin our study regularly used intermittent glides and bounds whenflying at velocities between 8 and 12 m s^-1 (94±9% oftheir total number of flights at these velocities).

Continuous variation in angle of attack ( ${alpha}$ ) within wingbeats (Fig. 9)indicated that bound circulation on the wing is likely to varythroughout the wingbeat cycle of hummingbirds, and this variationshould be evident in the wake as cross-stream starting and stoppingvortices that parallel the long axis of the wings (Rayner, 1986; Rayner,1988; Tobalske, 2000). We interpret that this will give riseto some form of `ladder' appearance in the wake similar to thestructure described for the wake of the thrush nightingale duringfast forward flight (Spedding et al., 2003). Our ongoing researchinto the wake of flying hummingbirds using digital particleimage velocimetry (DPIV) appears to support this expectation(Tobalske et al., 2005b; Warrick et al., 2005).

Relative to incurrent air, the wing functioned as an invertedairfoil during the upstroke of flight at 0 and 2 m s^-1. Theopposite sign, nearly symmetrical pattern of ${alpha}$ between the twohalves of the wingbeat cycle during hovering would appear tosupport a hypothesis that the two halves of the wingbeat arefunctionally identical (Stolpe and Zimmer, 1939; Greenewalt,1960a; Weis-Fogh, 1972; Wells, 1993), but a variety of smalldifferences in kinematics help to explain why the hovering upstroke producesless lift than the downstroke (Warrick et al., 2005). These includeslightly greater values of | ${alpha}$ | during early downstroke versusupstroke (Fig. 9), a different trajectory of the wingtips andwrists apparent in lateral projection (Fig. 2A and Fig. 7),and marginally greater angular velocity of the wing during downstroke (Fig. 5C).

Because ${alpha}$ and ${alpha}$ _c were measured at the middle of the wing as aline between the wrist and the tip of the first secondary, weare unable to address any potential effects of long-axis twistingof the wings (Bilo, 1971; Bilo, 1972; Willmott and Ellington, 1997a).Particularly during upstroke, the hummingbird wing twists sothat the proximal and distal sections of the wing exhibit differentangles relative to the body and, potentially, the incurrentair (Warrick et al., 2005). Data from other species (Bilo, 1971; Bilo,1972; Hedrick et al., 2002) suggest that twist about the long-axismay be present during the entire wingbeat. For example, changesin ${alpha}$ differ in magnitude and relative timing between the proximaland distal wing of the cockatiel (Hedrick et al., 2002).

New research on the patterns of wing motion in birds would,therefore, benefit from adopting a more complete protocol formeasuring ${alpha}$ _c and ${alpha}$ along the entire wing. The strip method recommendedfor use in studies of insect flight may be appropriate (Willmottand Ellington, 1997a). A challenge for applying this methodto birds is that cross-sectional profile and camber vary greatlyalong the avian wing, but laser scanning shows promise for creatinguseful 3D models (Liu et al., 2004). Profile, camber, ${alpha}$ _c and ${alpha}$ may vary throughout the wingbeat of birds (Bilo, 1971; Bilo,1972) (Figs 4, 5 and 9). This variation is probably due aeroelasticity(Bisplinghoff et al., 1955), neuromuscular control (Dial, 1992a)and interactions between the two (Natarajan, 2002). Consequently,an effort to measure additional details of wing kinematics willremain pivotal to advancing understanding of bird flight.

Looking toward future research on flight performance in hummingbirds, cautionis required when interpreting our measures of ${alpha}$ . Two measures indicatethat unsteady aerodynamic effects (Spedding, 1993; Dickinsonet al., 1999) dominated during slow flight and were perhapssignificant over the full range of velocity in our experiments.These effects likely make our estimate of V_i (Eqn 1, 2, 3) inaccurate,with concomitant effects on ${alpha}$ . The measures of unsteadiness areadvance ratio (J):

Formula 3 (4)
whereT=wingbeat duration, and reduced frequency (k):

Formula 5 (5)
where c=wing chord (Table 1).In our experiments, J was 0 during hovering and increased from0.3±0.06 during flight at 2 m s^-1 to 1.3±0.2 duringflight at 12 m s^-1. When J=1, the forward distance traveledby the body during one wingbeat is equal to the distance traveledby the wingtip (Rosén et al., 2004). J was 0.8±0.02during flight at 6 m s^-1 and 1.12±0.03 during flightat 8 m s^-1. The expected overlap of projected paths of the wingtipswith J<1 is apparent for slower velocities (0-4 m s^-1) inFig. 7, indicating that the wingtips may interact with flowin the wake. For comparison, the thrush nightingale exhibitsvalues for J decreasing from 1.2 to 0.6 over the range from5 to 10 m s^-1, reaching a value of J<1 at 7 m s^-1 (Rosénet al., 2004).

With similar consequences for the predicted likelihood of unsteadyflow patterns, k in hummingbirds varied from a maximum of 0.66±0.08 duringflight at 2 m s^-1 to 0.11 during flight at 12 m s^-1 (k is undefinedfor hovering, Eqn 5). Spedding (Spedding, 1993) suggests that unsteadyeffects are likely to be significant to the flow about the wingswhen k>1 and that they may be ignored when k<0.1. Hummingbirdsdid not achieve k<0.1 even at their fastest sustained velocity.Thrush nightingales also do not achieve this value, with a minimum kof 0.2 during flight at 10 m s^-1 (Rosén et al., 2004). Giventhe complexity of the avian wingbeat, k is only a rough predictorfor the likelihood of unsteady flow (Rosén et al., 2004). Nonetheless,our results reveal that the potential contribution of unsteady flowshould be taken into consideration in future experiments onflight aerodynamics in hummingbirds.

List of symbols

${alpha}$: angle of attack of wing
${alpha}$ c: chord angle relative to mid-frontalplane of body
ß: body angle relative to horizontal
${gamma}$ b: anatomical stroke-plane angle relative to mid-frontal planeof body
${gamma}$ h: tracking stroke-plane angle relative to horizontal
${rho}$: air density
${phi}$: wingbeat amplitude
${Psi}$ d: global downstroke-planeangle relative to horizontal
${Psi}$ u: global upstroke-plane anglerelative to horizontal
AR: aspect ratio
b: wing span
c: wingchord
CV: coefficient of variation
f: wingbeat frequency
g: gravitationalacceleration
k: reduced frequency
l: wing length
M_b: body mass
J: advance ratio
S_d: disc area
T: duration of wingbeat
V: free-streamvelocity
V_i: induced velocity

Acknowledgments

We thank Jim Usherwood and an anonymous referee for their helpfulcomments on a previous draft of the manuscript. Supported byMurdock Grants 99153 and 2001208 to B.W.T. and NSF Grants IBN-0327380and IOB-0615648 to B.W.T. and D.R.W.

References

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

Altshuler, D. L. and Dudley, R. (2002). The ecological and evolutionary interface of hummingbird flight physiology. J. Exp. Biol. 205,2325 -2336.[Abstract/Free Full Text]

Altshuler, D. L. and Dudley, R. (2003). Kinematics of hovering hummingbird flight along simulated and natural elevational gradients. J. Exp. Biol. 206,3139 -3147.[Abstract/Free Full Text]

Altshuler, D. L., Dudley, R. and McGuire, J. A. (2004). Resolution of a paradox: hummingbird flight at high elevation does not come without a cost. Proc. Natl. Acad. Sci. USA 101,17731 -17736.[Abstract/Free Full Text]

Barlow, J. B., Jr, Rae, W. H., Jr and Pope, A. (1999). Low-Speed Wind Tunnel Testing. New York: Wiley-Interscience.

Bartholomew, G. A. and Lighton, J. R. B. (1986). Oxygen consumption during hover-feeding in free-ranging Anna hummingbirds. J. Exp. Biol. 123,191 -199.