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Jumping and flying

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Jumping and flying Movement in the air – PowerPoint PPT presentation

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Title: Jumping and flying


1
Jumping and flying
  • Movement in the air

2
Aim
  • jumping
  • gliding
  • powered flight
  • insects
  • birds

3
References
  • Schmidt - Nielsen K (1997) Animal physiology
  • McNeill Alexander R (1995) CD Rom How Animals
    move
  • Journals Web links see
  • http//biolpc22.york.ac.uk/632/movelectures/fly/
  • Extra reference
  • Videler, J (1993) Fish swimming Chapman Hall

4
Jumping
  • What limits how far we can jump?
  • At take off have all energy stored as KE
  • conversion of kinetic energy to potential
    (gravitational) energy
  • KE ½ m v2
  • PE mgh

5
How high
  • depends on KE at take off
  • PE KE therefore mgh ½ mv² or gh ½ v²
  • If muscle is M, let work done be kM
  • mgh kM or h kM/(mg) (k/g)(M/m)
  • If same proportion of body is jumping muscle,
    height should be the same
  • no effect of mass on how high you jump
  • neglects air resistance

6
How far do we go?
  • depends on take off angle
  • d (v² sin 2a) /g
  • jumping.xls
  • maximum at 45o
  • Sin 90 1
  • d v2/g

7
How far
  • maximum distance 2KE/ (mg)
  • 2 (kM)/(mg)2(k/g) (M/m)
  • as before distance not affected by body mass

Alice Daddy
age 8 ??
mass 35kg 87kg
distance 1.16m ??
8
Great locust jumping test
No wings
3rd instar adult
mass
distance
9
How long to take off?
  • depends on leg length
  • time to generate force is 2s/v
  • for long jump, time 2s/?(gd)
  • s is leg length, d is distance jumped
  • bushbaby 0.05 to 0.1s
  • frog 0.06s
  • flea 1 ms
  • locust ??

10
Jumping in locusts
  • If we could jump as well, we could go over the
    Empire state building
  • elastic energy storage
  • co-contraction

11
Running jump
  • much higher/further
  • KE can be stored in tendons and returned during
    leap

12
Summary so far
  • Jumping is energetically demanding
  • muscle mass body mass is most important
  • store energy in tendons if possible

13
Flying
  • gliding
  • power flight
  • hovering
  • How stay up?
  • Can nature do better than mankind?

14
Who flies?
  • insects
  • birds
  • bats
  • pterosaurs

15
Lift
  • why dont birds fall due to gravity?
  • where does lift come from?
  • speed up air
  • Bernoullis Principle
  • Total energy pressure potential energy
    gravitational potential energy kinetic energy
    of fluid

16
How does air speed up?
  • air slows down underneath because wing is an
    obstacle
  • air speeds up above wing
  • fixed amount of energy

17
Lift and vortices
  • faster /slower airflow
  • circulation
  • extends above / below for length of wing
  • creates wake

18
Circulation
  • circulation vortex shed at wingtips

19
How much lift
  • lift increases with speed 2
  • lift increases with angle of attack

20
So to fly
  • we need to move through the air
  • use PE to glide down
  • as go down, PE changed to KE
  • use wings to force a forwards movement

21
Fly optimally?
minimum power
maximum range
22
Can nature beat man?
23
Gliding
  • soaring in thermals
  • Africa thermals rise at 2-5m/s
  • soaring at sea/by cliffs

24
Bigger is better?
  • big wings act on more air
  • called lower wing loading
  • long thin wings have less induced power
  • called aspect ratio
  • more economical, but have to fly faster

25
Bigger is worse
  • As bird size (l) gets bigger
  • mass ? l3
  • wing area ? l2
  • wing loading must go up ? l
  • big birds need more wing area than little birds
  • harder to flap

26
Summary so far
  • Jumping is energetically demanding
  • muscle mass body mass is most important
  • store energy in tendons if possible
  • Flying involves generating lift
  • gliding
  • use PE to get KE to get speed to get lift

27
Flapping flight
  • large birds fly continuously
  • down stroke air driven down and back
  • up stroke
  • angle of attack altered
  • air driven down and forwards
  • continuous vortex wake

28
Discontinuous lift
  • small birds with rounded wings
  • lift only on downstroke
  • vortex ring wake
  • http//www.biology.leeds.ac.uk/staff/jmvr/Flight/
    modelling.htm

29
Bounding flight
  • glide, flap, glide, flap,
  • flap - several times, then glide
  • full muscle power would make bird climb
  • more efficient to use muscle at best shortening
    rate

30
Hovering flight
  • humming bird hovering
  • generates lift on forward and back stroke
  • as wings beat, vortices shed at end of stroke

31
Insect flight
  • flexibility of wings allows extra opportunities
    to generate lift
  • rotation of wing increases circulation

32
Insect flight
lift
  • flexibility of wings allows extra opportunities
    to generate lift
  • fast flight of bee
  • downstroke
  • upward lift
  • upstroke

bee
move wing
33
Clap and fling
  • at top of upstroke two wings fuse
  • unconventional aerodynamics
  • extra circulation
  • extra force

34
Wake capture
  • wings can interact with the last vortex in the
    wake to catch extra lift

first beat
second beat
35
Summary
  • Jumping is energetically demanding
  • muscle mass body mass is most important
  • store energy in tendons if possible
  • Flying involves generating lift
  • gliding
  • use PE to get KE to get speed to get lift
  • flapping propels air
  • insects often have unconventional aerodynamics

36
Exam papers
  • Neuroscience (i)  Matsuda K, Buckingham SD,
    Kleier D, Rauh JJ, Grauso M, Sattelle DB. (2001)
    Neonicotinoids insecticides acting on insect
    nicotinic acetylcholine receptors  Trends
    Pharmacol Sci.  22 573-80
  • Neuroscience (ii) Cho, W, Heberlein U, Wolf, FW
    (2004) Habituation of an odorant-induced startle
    response in Drosophila Genes, Brain, And Behavior
    3 127-137 paper copy here
  • Muscle  Kappler, JA Starr, CJ Chan, DK
    Kollmar, R Hudspeth, A J (2004) A nonsense
    mutation in the gene encoding a zebrafish myosin
    VI isoform causes defects inhair-cell
    mechanotransduction Proc Natl Acad Sci U S
    A. 10113056-61
  • Movement  Prestwich, KN O'Sullivan, K (2005)
    Simultaneous measurement of metabolic and
    acoustic power and the efficiency of sound
    production in two mole cricket species
    (Orthoptera Gryllotalpidae) J exp Biol 208,
    1495-1512

37
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