1. Age structured populations
Alfred James Lotka ( )
Vito Volterra ( )

2. First steps in life tables
Mortality rate
Survival rate
Fecundity
Age N f d l
1000
0.15
0.85 10
600
0.09
0.91 20
700
0.1 30
595
1.2
0.25
0.75 40
446
0.6
0.35
0.65 50
290
0.3
0.38
0.62 60
180
0.05
0.42
0.58 70
200
0.55
0.45 80 90
0.95
100 3 1
N0 is the number of newborns.
N is the number of females per age cohort.
Fecundity f is the average number of offspring per female.
d is the mortality rate per cohort.
l is the fraction of survivors per cohort.

3. The pivotal age is the averge age per age cohort class Age t N D d l
Number of deaths at each age classage
The pivotal age is the averge age per age cohort class
Pivotal age
Age t N D d l
1000 10 5
850
150
0.150
0.850 20 15
835
0.018
0.982 30 25
812 23
0.028
0.972 40 35
777
0.043
0.957 50 45
737
0.051
0.949 60 55
661 76
0.103
0.897 70 65
551
110
0.166
0.834 80 75
270
281
0.510
0.490 90 85
167
103
0.381
0.619
100 95 7
160
0.958
0.042
105 1 6
0.857
0.143
120
115
1.000
0.000
The basic information needed is the total number of deaths per age cohort.
survival
mortality
𝑑 𝑥 = 𝐷 𝑥 𝑁 𝑥
𝑙 𝑥 =1− 𝑑 𝑥 = 𝑁 𝑥 𝑁 𝑥−1
Mortality rate
survival rate

4. First steps in life tables
Death rate
Survival rate
Fecundity
Age N0 f d l N1
1000
0.15
0.85
1148 10
600
0.09
0.91
850 20
700
0.1
546 30
595
1.2
0.25
0.75 40
446
0.6
0.35
0.65 50
290
0.3
0.38
0.62 60
180
0.05
0.42
0.58 70
200
0.55
0.45
104 80 90
0.95 23
100 3 1
=E27*H27
N1(0) 70
714
268 87 9
=+E28*F28
Population size of each cohort after reproduction
Initial age distribution
Age distribution of the next generation
𝑁 1 0 = 𝑁 𝑖 × 𝑓 𝑖
𝑁 = 𝑁 0 (0)×𝑙(0)

5. If the population is age structured and contains k age classes we get10 20 30 40 50 60 70 80 90
100
0.1
1.2
0.6
0.3
0.05
0.85
0.91
0.75
0.65
0.62
0.58
0.45
0.25 N0 N1
1000
1148
600
850
700
546
595
446
290
180
200
104 90 50 23 3
Fecundities
Survival rates
Leslie matrix
N0(0) = 1000
N0(1) = 1148
595*0.75=446
The mutiplication of the abundance vector with each row of the Leslie matrix gives the abundance of the next generation.

6. We have w-1 age classes, w is the maximum age of an individual.
Leslie matrix
We have w-1 age classes, w is the maximum age of an individual.
L is a square matrix.
Numbers per age class at time t+1 are the dot product of the Leslie matrix with the abundance vector N at time t
The Leslie model is a linear approach.
It assumes stable fecundity and mortality rates

7. At the long run population size increases.
Going Excel
Age 10 20 30 40 50 60 70 80 90
100
0.1
1.2
0.6
0.3
0.05
0.85
0.91
0.75
0.65
0.62
0.58
0.45
0.25 N0 N1 N2 N3 N4 N5 N6
1000
1148
1132
998
1183
1366
1413
600
850
976
963
848
1005
1161
700
546
774
888
876
772
915
595
464
657
755
744
656
446
348
493
566
558
290
226
321
368
180
140
199
200
104 81 90 47 50 23 12 3 1
Demographic low
At the long run population size increases.
Diagonal waves in abundances occur.
The first age cohort increases fastest.

8. The effect of age in reproduction10 20 30 40 50 60 70 80 90
100
0.1
1.2
0.6
0.3
0.05
0.85
0.91
0.75
0.65
0.62
0.58
0.45
0.25
Age 10 20 30 40 50 60 70 80 90
100
0.05
0.3
0.6
1.2
0.1
0.85
0.91
0.75
0.65
0.62
0.58
0.45
0.25
Reproduction in early age contributes more to population size than later reproduction.
This is caused by the higher number of females in earlier cohorts.

9. The effect of the initial age composition disappears over time
Age composition approaches an equilibrium although the whole population might go extinct.
Population growth or decline is often exponential
Age 10 20 30 40 50 60 70 80 90
100
0.1
1.2
0.6
0.3
0.05
0.25
0.91
0.85
0.75
0.65
0.62
0.58
0.45
High early death rates cause fast population extinction and would need high fecundities for population survival

10. This vector is the eigenvector U of the matrix.
Does the Leslie approach predict a stationary point where population abundances doesn’t change any more?
𝑵 𝑡+1 = 𝑅𝑵 𝑡
𝑵 𝑡+1 = 𝑳𝑵 𝑡 = 𝑵 𝑡
𝑵 𝑡+1 = 𝑅 𝑡 𝑵 0
𝑵 𝑡+1 = 𝑳 𝑡 𝑵 0
We’re looking for the stable state vector that doesn’t change when multiplied with the Leslie matrix.
This vector is the eigenvector U of the matrix.
Eigenvectors are only defined for square matrices.
𝑳𝑼=𝜆𝑼
𝑵 𝑡+1 = 𝑳𝑵 𝑡 =𝜆 𝑵 𝑡 =𝑅 𝑵 𝑡
Important properties:
Eventually all age classes grow or shrink at the same rate
Initial growth depends on the age structure
Early reproduction contributes more to population growth than late reproduction
The largest eigenvalue l of a Leslie matrix denotes the long-term average net reproduction rate.
The right (dominant) eigenvector contains the stable state age distribution.

11. Eggs Larva 1 Larva 2 Larva 3 Imago Eggs Larva 1 Larva 2 Larva 3 Imago
Leslie matrices in insect populatons
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
2000
0.25
0.15
0.1
Largest eigenvalue r = l = 1.02
2000 female eggs per individual are cause a steady population increase. This relates to 4000 eggs when including males.
Leslie matrices deal with effective populations sizes.
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
200
0.25
0.15
0.1
Largest eigenvalue r = l = 0.65
The population steadily declines.
𝑵 1 = 𝑳𝑵 0 N0
Eggs
Larva 1
Larva 2
Larva 3
Imago
100000
11250
1265.6
25000
2813
2812.5
3750
421.9
421.88
563
562.5
63.28
63.281 56
56.25
6.3281
The diagonal matrix elements show how many individuals survive.

12. Eggs Larva 1 Larva 2 Larva 3 Imago U U
Stable age distribution
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
2000
0.25
0.15
0.1
𝑵 𝑡+1 = 𝑳𝑵 𝑡 =𝜆 𝑵 𝑡
The largest eigenvalue l of a Leslie matrix denotes the long-term net population growth rate R.
The right (dominant) eigenvector contains the stable state age distribution. U U
Nstable
Sum 1
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
For the population to survive the number of first instars has to be / = 477 time larger than the number of imagines.
U =
l = 1.02
Stable age class distribution

13. Eggs Larva 1 Larva 2 Larva 3 Imago U U
Remaining in the same age class
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
0.10
2000
0.25
0.15
0.05
0.1
0.5
The probability that an egg survives and remaines in the egg state is 0.10
The probability that an imago survives and reproduces in the next generation is 0.5.
This is the case in biannual insects (for instance some Carabus)
𝑵 𝑡+1 = 𝑳𝑵 𝑡 =𝜆 𝑵 𝑡
Largest eigenvalue R = l = 1.21
l = 1.21
l = 1.02 U U
Nstable
Sum 1
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
Nstable U=
Without staying the same
Stable age class distribution

14. High mortality, high fecundity r strategist species
Sensitivity analysis
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
2000
0.25
0.15
0.1
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
2.5
0.95
0.91
0.93
l = 1.02
l = 1.14
High mortality, high fecundity
r strategist species
Low mortality, low fecundity
K strategist species
l > 1 → effective population size increases
How robust is l with respect to changes in survival and fecundity rates?
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
1.4
0.95
0.91
0.93
l = 1.01
The lowest possible fecundity is 1.4 female eggs per female.

15. Increasing mortality rates until the population stops increasing
Sensitivity analysis
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
2.5
0.95
0.91
0.93
l = 1.14
Increasing mortality rates until the population stops increasing
Age
Eggs
Larva 1
Larva 2
Larva 3
Imago
2.5
0.86
0.819
0.837
0.855
l = 1.05
Mortality rates might be 10% higher to remain effective population sizes still increasing.

16. Average number alive in a cohort Cumulative number alive in a cohort
Survivorship tables
Number of death
Death rate
Average number alive in a cohort
Cumulative number alive in a cohort
Survival rate
Average life expectation
Age N
1000 10
850 20
835 30
812 40
777 50
737 60
661 70
551 80
270 90
167
100 7
110 1
120 D
150 15 23 35 40 76
110
281
103
160 6 1 l
0.85
0.98
0.97
0.96
0.95
0.90
0.83
0.49
0.62
0.04
0.14
0.00
+H25/H24 d
0.15
0.02
0.03
0.04
0.05
0.10
0.17
0.51
0.38
0.96
0.86
1.00
+J25/H24 L
925
843
824
795
757
699
606
411
219 87 4 1
+(H25+H24)/2 SL
6168
5243
4401
3577
2783
2026
1327
721
310 92 5 1
+SUMA(L$24:L24) e
61.7
52.7
44.1
35.8
27.5
20.1
13.1
11.5
5.5
6.4
5.0
+M24/H24*$G$14
𝐿 𝑥 = 𝑁 𝑥 +𝑁(𝑥+1) 2
Σ𝐿= 𝑥 𝑚𝑎𝑥 𝐿(𝑥)
𝑒 𝑥 = Σ 𝐿 𝑥 𝑁 𝑥 𝑘
k = length of cohort (10 years)

17. The female life table of Polish women 2012 (GUS 2013)
Age N D l d L SL e
100000
99787 1
99574
426
99563 2
99552 21 3
99537 15
99531 4
99525 11
99520 5
99515 10 6
99506
99501 7
99496 9 8
99487
99483
99479
99470
99461 12
99452
99446 13
99440 14
99427
99412 16
99393 18
99383 17
99373
99350 23
99338 19
99326 24
99314 20
99302
99290
Average life expectancy at birth
𝐿 𝑥 = 𝑁 𝑥 +𝑁(𝑥+1) 2
Σ𝐿= 𝑥 𝑚𝑎𝑥 𝐿(𝑥)
𝑒 𝑥 = Σ 𝐿 𝑥 𝑁 𝑥 𝑘 98
4317
1524
3710
8889.5 99
3103
1214
2634
5179.5
100
2165
938
1814
2545.5
>100
1463
702
731.5
0.5
>120 1

18. Polish survivorship curve 2012
Type I
Type I, high survivorship of young individuals: large mammals, birds
Type II, survivorship independent of age, seed banks
Type III, low survivorship of young individuals, fish, many insects
Type II
Type III
Polish mortality rates 2012
Newborns
New motocycle and car drivers

19. Average life expectancy at birth in Poland
81 years
Women
8 years
72 years
Men
Average life expectancy at age 60 in Poland
84 years
5 years
78 years

20. Reproduction life tables
Pivotal age
Survival rate
Number offspring
Birth rate R
Age t N0 D l
1000 10 5
850
150
0.85 20 15
835
0.98 30 25
812 23
0.97 40 35
777
0.96 50 45
737
0.95 60 55
661 76
0.90 70 65
551
110
0.83 80 75
270
281
0.49 90 85
167
103
0.62
100 95 7
160
0.04
105 1 6
0.14
120
115
0.00
Sum
+I25/I24 B b
0.000 20
0.024
515
0.634
342
0.440 59
0.080 2
0.003
=L25/I25 lb
0.000
0.024
0.617
0.421
0.076
0.003
1.140
+M25*K25
lbt
0.0
0.4
15.4
14.7
3.4
0.1
34.096
29.9
+N25*H25
𝐺= 𝑙 𝑖 𝑏 𝑖 𝑡 𝑖 𝑙 𝑖 𝑏 𝑖
The mean generation length is the mean period elapsing between the birth of parents and the birth of offspring.
It is the weighted mean of pivotal age weighted by the number of offspring.
𝑅 0 = 𝑅 𝑖 = 𝑙 𝑖 𝑏 𝑖
Net reproduction rate

21. Reproductive value at age x
Species
Body mass (kg)
Litter size
Age of maturity (yr)
Life expectancy (yr)
Life expectation at maturity (yr)
Reproductive value at maturity
Generation length (yr)
Castor canadensis 18
6.6 2
1.52
2.22
5.63
4.87
Clethreonomys glareolus
0.025 5
0.11
0.16
0.48
7.9
0.33
Peromyscus leucopus
0.02
0.15
0.21
0.28
4.52
0.27
P. maniculatus
3.6
0.23
0.43
5.04
0.35
Sciurus carolinensis
0.6
2.9 1
1.37
2.17
5.95
2.07
Spermophilus armatus
5.3
1.38
1.72
1.78
S. beldingi
0.25
7.4
1.3
5.89
1.56
S. lateralis
0.155
5.2
1.47
2.12
5.08
2.45
S. parrylii
0.7
7.3
1.28
1.71
6.17
1.59
Tamias striatus
0.1
4.2
1.24
1.63
6.84
Tamiasciurus hudsonicus
0.189 4
1.5
4.9
1.95
Ochotona princeps
0.13
2.8
2.33
6.51
Sylvilagus floridanus
1.25
1.48
2.62
1.29
Lutra canadensis
7.2 3
2.88
3.79
5.07
Lynx rufus
7.5
2.48
3.48
2.87
Mephitis mephitis
2.25 6
1.33
1.9
5.71
Taxidea taxus
7.15
1.45
Equus burchelli
270
3.84
7.95
8.74
Aepycerus melampus 44
3.44
4.8
2.42
4.36
Cervus elaphus
175
3.85
1.73
5.7
Connochaetes taurinus
165
4.79
2.56
6.29
Hemitragus jemlahicus
100
3.97
4.71
5.43
Hippopotamus amphibicus
2390 10
7.62
16.4
3.98
19.82
Kobus defassa
200
3.35
5.87
2.94
Ovis canadensis 55
3.81
5.48
2.74
6.52
Phacochoerus aethiopicus 87
1.6
2.82
6.76
4.28
Sus scrofa 85
1.79
1.91
4.82
3.15
Syncerus caffer
490
4.47
2.41
6.98
Loxodonta africana
4000 15
17.9
19.1
2.24
25.8
Life history data and body size
Reproductive value at age x
𝑅𝑉 𝑥 = 𝑓 𝑥 + 𝑦=𝑥+1 𝑚𝑎𝑥 𝑙 𝑦 𝑙 𝑥 𝑓 𝑦 𝑙 𝑦 𝑏 𝑦 𝑥−𝑦
Life history data are allometrically related to body size.
Data from Millar and Zammuto 1983, Ecology 64: 631

22. The characteristic life expectancy
The Weibull distribution is particularly used in the analysis of life expectancies and mortality rates
𝑓 𝛼,𝛽,𝑡 =𝛼𝛽 𝑡 𝛽−1 𝑒 −𝛼 𝑡 𝛽
𝑓 𝛼,𝛽 𝑑𝑡=𝐹 𝛼,𝛽,𝑡 =1− 𝑒 −𝛼 𝑡 𝛽
a=1
b=0.1 b=0.5
b=1.0 b=2.0 b=3.0

23. We interpret the time t as the time to death.
𝑓 𝛼,𝛽,𝑡 =𝛼𝛽 𝑡 𝛽−1 𝑒 −𝛼 𝑡 𝛽
We interpret the time t as the time to death.
b > 1: Probability of death increases with time b = 1: Probability of death is constant over time b < 1: Probability of death decreases with time
𝛼= 1 𝑇 𝛽
𝑓 𝛽,𝑡 = 𝛽 𝑇 𝑡 𝑇 𝛽−1 𝑒 − 𝑡 𝑇 𝛽
𝑓 𝛽 𝑑𝑡=𝐹 𝛽,𝑡 =1− 𝑒 − 𝑡 𝑇 𝛽
The two parameter Weibull probability density function
Characteristic life expectancy T
𝐹 𝛽,𝑡 =1− 𝑒 − 𝑡 𝑇 𝛽 ; t = T
2.2
𝐹 𝛽,𝑡 =1− 𝑒 −1 ≈0.632
The characteristic life expectancy T is the age at which 63.2% of the population already died.
F is the cumulative number of deaths.

24. How to estimate the characteristic life expectancy?
𝐹=1− 𝑒 − 𝑡 𝑇 𝛽
ln⁡(1−𝐹)=− 𝑡 𝑇 𝛽
ln − ln 1−𝐹 =𝛽 ln 𝑡 −𝛽ln⁡(𝑇)
Linear function Y = bX + C
𝑇= 𝑒 𝐶 −𝛽
Age t N0 D SD F
ln(-ln(1-F))
ln(t)
1000 10 5
630
370
0.37
-0.772
1.609 20 15
420
210
580
0.58
-0.142
2.708 30 25
250
170
750
0.75
0.327
3.219 40 35
110
140
890
0.89
0.792
3.555 50 45 60
940
0.94
1.034
3.807 55 34 26
966
0.966
1.218
4.007 70 65 19
985
0.985
1.435
4.174 80 75
995
0.995
1.667
4.317 90 85 3 2
997
0.997
1.759
4.443
100 95 1
999
0.999
1.933
4.554
105
+U25/S$13
b = 0.95
𝑇= 𝑒 −2.54 −0.95 =14.4
C = -2.54
Type III survivorship curve

25. The female life table of Polish women 2012 (GUS 2013)
Age N D F
ln(-ln(1-F))
ln(age)
100000 1
99574
426
-5.456
0.000 2
99552 21
-5.408
0.693 3
99537 15
-5.375
1.099 4
99525 11
-5.351
1.386 5
99515 10
-5.330
1.609 6
99506
-5.310
1.792 7
99496 9
-5.292
1.946 8
99487
-5.274
2.079
99479
0.0052
-5.256
2.197
99470
-5.241
2.303
Mortalities at younger age do not follow a Weibull distribution 86
41622
3983
-0.132
4.454 87
37586
4037
-0.022
4.466 88
33550
4035
0.6645
0.088
4.477 89
29573
3978
0.197
4.489 90
25710
3863
0.306
4.500 91
22020
3690
0.414
4.511 92
18551
3469
0.8145
0.522
4.522 93
15352
3199
0.628
4.533 94
12461
2891
0.8754
0.734
4.543 95
9906
2556
0.838
4.554 96
7699
2207
0.942
4.564
𝑇= 𝑒 𝐶 −𝛽
T = 86.8 years
The characteristic life expectancy of Polish woman in 2012 was 87 years

26. The female life table of Polish women 2012 (GUS 2013)
Maximum mortality 87
Mortality of newborns