fundamentals of fisheries resource management ramon carcamo fisheries expert
TRANSCRIPT
Fundamentals of Fisheries Resource Management
Ramon Carcamo
Fisheries Expert
Fisheries Resources
Organic resources are the same limited resources as mineral ones. If we exhausted mineral resources, mineral resources will run out. But, as organic resources have reproductive mechanism and differ from mineral resources, we can make the best use of organic resources for permanent utilization by applying their reproductive mechanism.
Fisheries resources is also organic resources, therefore, we have to consider permanent utilization of them by applying the mechanism.
Pillage fisheries will extinguish not only fisheries resources but also fisheries themselves.
Features of the fisheries resources
Non-renewable
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Organic [Living] Resources(Fish, shrimp, etc.---)
Reproductive Capability
No Management for Fisheries Resources
Depleted Fisheries Resources
Appropriate Fisheries Resource Management
Sustainable Use of (Fisheries) Resources
Mineral Resources (Oil, Coal, etc. ---)
Reproductive Capability
Características de los Recursos
Pesqueros No-renovables
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Recursos orgánicos [Vivientes](Peces, camarones, etc.---)
Reproductive Capability
Ningún Manejo para el Recurso Pesquero
Disminución del Recurso Pesquero
Apropiado Manejo del Recurso Pesquero
Uso Sostenible del Recurso (Pesquero)
Recursos minerales (Gasolina, carbón, etc. ---)
Capacidad Reproductiva
Fisheries Resources
Looking back the history on utilization and development of fisheries resources, the necessity of permanent utilization is quite obvious.
The major aim of fisheries resources conservation and management strategies is to make possible of permanent utilization of the resources.
We must grasp the strategies of fisheries resources conservation and management from three aspects.
The first aspect is a biological aspect, the second is a fisheries aspect, and the third is a economic aspect.
Biological Aspect: Growth law and survival law
The growth law shows the corresponding body weight increases as the cohort ages. WHILE,
Nu
mb
er o
r W
eigh
t
Age
Growth Curve
Survival Curve
The survival law demonstrates the decline in survival as a function of the age of the cohort.
Biological Aspect: Biomass curve
In the natural environment, the relationship of the two laws can be shown as a biomass curve.
Nu
mb
er o
r W
eigh
t
Age
X
The first half of the curve draws an exponential growth in total body weight of fish and as maturity is reached the maximum biomass , and will be at Point X.
Beyond this point little growth occurs and natural mortality begins to set in.
Simplified migration circuit
For maintain the resources on target species, proper measures for protection of nursery and spawning areas should be taken.
Adult Stock
Migration
Spawning Area
Migration / Drifting
Nursery Area
Recruitment
Fisheries Aspect: Selectivity curve 1.0
0.5
0.0
Body Size Y
Mes
h S
elec
tivi
ty Y
X
The selectivity curve is influenced by mesh size whereby as mesh size decreases, the curve moves to the left resulting in a smaller-sized catch.
Increasing the mesh size shifts the curve to the right, thus yielding a larger-sized catch. To maximize a catch, mesh size targeting the desired individuals should be used.
Fisheries Aspect: Discontinuous selectivity of an ideal gear
Previous mentioned relationship is drawn as a discontinuous selectivity curve (ideal gear if available)
1.0
0.5
0.0
Body Size
Mes
h S
elec
tivi
ty
No smaller fishes caught
Commercial sized fishes caught
Fisheries Aspect: Selectivity curve of diamond and square mesh
The mesh type is equally important as illustrated in above.
1.0
0.5
0.0
Body Size
M
esh
Sel
ecti
vity
Diamond Mesh
Square Mesh
At a given mesh size, square mesh is more effective in catching larger-sized fish than a diamond mesh.
In practice, this is a useful technique in catch selectivity.
Economic Aspect: Relationship between cost and Yield
MSY: Maximum Sustainable Yield
Fishing Effort
A
mou
nt
of M
oney
Yield
Cost MSY
MEY
MEY: Maximum Economic Yield
Objective
Target point at the time
Observation of present state
Evaluation of the difference from the target point
Judgment of method to approach target point
Decision on measure to be taken
Fisheries resource management at the target area
Monitoring of results
Scientific research
Fisheries Resource Management System in General
Flow chart of the measures for
sustainable use of the fisheries resources Fishermen (Fishers)
Fishermen want to catch fish, shrimp, shellfish, etc. as possible as they can.
Paid the heavy effort for the fisheries resources without management measures.
Depleted fisheries resources
Fishermen can’t be survived as fishermen & no fish will be provided to the consumers.
Appropriate fisheries management measures have to be promoted for sustainable use of the fisheries resources.
Establish Fisheries Resource Management Committee.
Policy makerResearcherFisheries industry
Intelligent persons in the fisheries science
Appropriate fisheries management measures have to be promoted for sustainable use of the fisheries resources.
Diagrama de flujo de las medidas para un
uso sostenible de los Recursos Pesqueros Pescador (Pescadores)
El pescador quiere capturar peces, camarones, moluscos, etc. tantos como ellos puedan.
Pago por el fuerte esfuerzo por los recursos pesqueros sin medidas de manejo.
Disminución de los recursos pesqueros
Pescador no puede sobrevivir como tal y los peces no son suministrados a los consumidores.
Appropriate fisheries management measures have to be promoted for sustainable use of the fisheries resources.
Establecen un Comité de Manejo de los Recursos Pesqueros.
Vigilancia
InvestigaciónIndustria pesqueraPersonas Inteligentes en la Ciencia pesquera
Apropiadas medidas de manejo pesquero deben ser promovidas para un uso sostenible de los recursos pesqueros.
Major information needed for fisheries resource management (ⅰ) Biological Information (ⅱ) Technical Information (ⅲ) Economic Information (ⅳ) Social Information and (ⅴ) Institutional Information
– Source: FAO, RAPA Rep., 1987/10 Information mentioned above is obtained from
many sources such as universities, extension agents and so on.
For the more effective use of sources of information and increasing supply to information, some possible approaches suggested are as follow:
(ⅰ) Increasing contact with fishermen by facilitating establishment of fishermen’s groups or organizations or by making greater use of extension agents.
(ⅱ) Improved communication between decision-makers and scientists through the establishment of consultative meetings etc.
For the more effective use of sources of information:
(ⅲ) Better coordination between fisheries statistical services and other government agencies.
(ⅳ) Integrating the collection of economic and social data into catch assessment surveys.
For the more effective use of sources of information:
(ⅴ) Development and testing of surrogate-indicators for detailed information (e.g., changes in shares paid for labour or in lease fees for vessels as indicators of health of fisheries).
(ⅵ) Greater involvement of universities in multi-disciplinary fisheries research of direct relevance for decision-making.
(ⅶ) Improved contacts between private fishing industry and
fishery administrators.
(ⅷ) Others.
DEFINE THE FISHERY- GEOGRAPHICAL BOUNDARIES- FISHING METHODS- FISH SPECIES (ONLY IF ESSENTIAL)
ESTABLISH AN INDUSTRY/GOVERNMENT TASK FORCE
DETERMINE THE OBJECTIVE FOR MANAGEMENT OF THE FISHERY
CONSOLIDATE AND ANALYSE AVAILABLE BIOLOGICAL, ECONOMIC AND LICENSING INFORMATON
PREPARE MANAGEMENT OPTIONS PAPER SETTING OUT:- DESCRIPTION OF FISHERY- OBJECTIVES- ASSESSMENT OF BIOLOGICAL AND ECONOMIC DATA- ASSESSMENT OF MANAGEMENT OPTIONS UNDER FOLLOWING HEADINGS .. OPEN ACCESS .. TAXES ON INPUTS OR OUTPUTS .. LIMITED ENTRY .. INDIVIDUAL TRANSFERABLE QUOTAS
DRAFT MANAGEMENT PROPOSALS FOR CONSIDERATION BY INDUSTRY
SUBMISSION O RECOMMENDATIONS TO GOVERNMENT
ESTABLISHMENT OF INDUSTRY/GOVERNMENT MANAGEMENT ADVISORY COMMITTEE
IMPLEMENTATION OF MANAGEMENT PLAN
ONGOING EVALUATION OF MANAGEMENT PLAN AND INTRODUCTION OF ADDITIONAL MANAGEMENT MEASURES
An example of ‘Process of formulation of fisheries resource management plan’ is shown as follows (FAO, RAPA Rep., 1987/10)
Fisheries Resource Management Ideas for Small-scale Fisheries
Fishery BiologyFishery Biology
Stock AssessmentStock Assessment
Policy and MeasuresPolicy and Measures
Interaction of FisheriesInteraction of Fisheries
Resource EnhancementResource Enhancement
Fisheries StatisticsFisheries Statistics
Items should be done for the stock assessment and fisheries
resource management for the small-scale fisheries is as follow (Modified from Saila and Roedel, 1979):
(ⅰ) Collaborative Research, First Priority
① Comparative Studies – Productivity ② Comparative Studies - Catch ③ Comparative Assessment Models ④ Policy and Decision-making Structures ⑤ Biosocioeconomic Models
Items should be done for the stock assessment and fisheries
resource management for the small-scale fisheries is as follow (Modified from Saila and Roedel, 1979):
( ) Collaborative Research, Second Priorityⅱ
① Data Analysis Systems ② Surveys – Direct Census ③ Surveys - Acoustics
Items should be done for the stock assessment and fisheries
resource management for the small-scale fisheries is as follow (Modified from Saila and Roedel, 1979):
( ) Collaborative Research, Third Priorityⅲ
① Age and Growth Studies ② Surveys – Remote Sensing ③ Surveys – Capture ④ Surveys – Eggs and Larvae
Items should be done for the stock assessment and fisheries
resource management for the small-scale fisheries is as follow (Modified from Saila and Roedel, 1979):
( ) Supportive Research Activities ⅳ
① Inventory of Exploited Resources ② Inventory of Human and Institutional Resources
③ Inventory of Ecosystem Response ④ Inventory of Life Histories ⑤ Surveys - Effort
Items should be done for the stock assessment and fisheries
resource management for the small-scale fisheries is as follow (Modified from Saila and Roedel, 1979):
( ) Supportive Development Activities ⅴ
① Information Dissemination ② Training - Data
Stock Structure: Single-speciesS T O C K I
(Single-species)
Species A Regional Form a
Regional
Form b
Biological features on Form a
Biological features on Form b
Biological features on Species A
Resource evaluation on Stock I
Discrimination between Form a and Form b
(Resource evaluation on Form a)
(Resource evaluation on Form b)
Stock Structure: Multi-species
S T O C K II (Multi-species)
Species B
Species C
Biological features on Species B
Biological features on Species C
Resource evaluation on Stock II
(Resource evaluation on Species B)
(Resource evaluation on Species C)
Stock Discrimination
The stock or shoal discrimination studies are mainly based on the followings:
Morphology Ecology Catch fluctuation Genetics
Stock Discrimination Stock characters are as follows:
Body length and weight composition Growth rate Age composition Fatness Egg-diameter Fecundity Scale features
Stock Discrimination
Stock characters are as follows:
Ratio of body measurements Meristic characters Serum protein Karyotypes Isozymes Mitochondria DNA
Parameters/Elements for Biological Features of Fish
Popular parameters/elements for biological features are as follow:
① Geographic limits to the stock ② Migration pattern ③ Depth distribution ④ Size composition (mean length in catch,
maximum length and maturity size) ⑤ Spawning (season and area)
Parameters/Elements for Biological Features of Fish
Popular parameters/elements for biological features are as follow:
⑥ Nursery ground ⑦ Fecundity ⑧ Recruitment (season and body size) ⑨ Growth (growth rate) ⑩ Length-weight relationship
Parameters/Elements for Biological Features of Fish
Popular parameters/elements for biological features are as follow:
⑪ Mortality ⑫ Age and age determination ⑬ Sex ratio ⑭ Food and feeding habit ⑮ Predators
Parameters/Elements for Biological Features of Fish Additionally, meristic characters such as
number of vertebrae, number of fin spines and rays, number of mid-lateral scales and so on are very important elements, and morphometric characters are also important for the features of stock of fish.
Identification of Parameters for Studies on Stock and Population Dynamics
① Length-weight relationship: – Paired data of length and weight are required. – Data are obtained from measurements of fish
body.
② Growth curve: – Paired data of age and length are required. – Analyse age and measurements of fish body.
Identification of Parameters for Studies on Stock and Population Dynamics
③ Natural mortality coefficient: – Longevity (analyse age, etc.), growth equation (analyse
age and fish body measurements), tagging data (analyse recapture data) and data of virgin stock (survey in unexploited area) are required.
④ Fishing mortality coefficient: – Age composition (analyse age), catch and effort (obtain
from operation record) and tagging data (analyse recapture data) are required.
Identification of Parameters for Studies on Stock and Population Dynamics
⑤ Longevity: – Growth, sex ratio, survival rate, etc. are required.
– Analyse age, sex and etc.
⑥ Availability: – Species list and catch composition are required.
– Data are obtained from Fish Market Census or direct observation of fish market.
Identification of Parameters for Studies on Stock and Population Dynamics
⑦ Reproductive mechanism: – Information on recruitment-parent relationship
is required. – Analyse age composition data for many years.
⑧ Sex ratio: – Frequency distribution of each sex is required. – Analyse numbers of male and female
determined by gonad.
Identification of Parameters for Studies on Stock and Population Dynamics
⑨ Maturity rate: – Frequency distribution of gonad index is
required. – Examine the gonads.
⑩ Number of spawned eggs: – Number of incubation and spawning eggs is
required. – Examine the ovaries.
Identification of Parameters for Studies on Stock and Population Dynamics
⑪ Age composition: – Frequency distribution of body length is
required. – Analyse age and body length frequency. Age
determination method is required.
⑫ Population index: – Fish density of each area is required. – Data are obtained from experimental surveys.
Identification of Parameters for Studies on Stock and Population Dynamics
⑬ Effective overall fishing intensity: – Fish density of each area is required. – Data are obtained from experimental surveys.
⑭ Catchability coefficient: – Selectivity and escape rate are required. – Data are obtained from experimental surveys.
Identification of Parameters for Studies on Stock and Population Dynamics
⑮ Selectivity: – Mesh size selectivity data are required. – Data are obtained from experimental surveys.
⑯ Escape rate: – Hypothetical experiment is required.
Identification of Parameters for Studies on Stock and Population Dynamics
⑰ Density of area: – Experimental survey is required.
⑱ Catch per year: – Fisheries statistics is required.
Possible Measures for Fisheries Management (Closed Season)
During this period Fishing activities are prohibited To protect spawning adults during the
spawning season Or To rehabilitate depleted stocks
Possible Measures for Fisheries Management (Closed Area)
An area/habitat is closed to fishing activities, For example, to protect spawning grounds or
juveniles This does not affect fishing effort It can be relocated to other areas But it can limit its effectiveness on fishing
effort
Possible Measures for Fisheries Management (Fishing Gear and Methods)
Certain types of fishing gear will be prohibited
Also the number of fishing gear will be restricted on this scheme
Mesh size restriction for certain fishing gear is also one of the popular measures
Possible Measures for Fisheries Management (Size Limit)
On the fishing and selling of fish Under a set size limit must be prohibited For conserving the resources Fish caught less than a set size limit It must be released into the sea At good condition.
Possible Measures for Fisheries Management (Fishing Sub-gear)
Fishing sub-gear such as fish luring (aggregative) lamp
It is sometimes restricted of its electric power Intensity of the lamps tends to be strengthened
gradually in order to get more catches But intensity of lamps is strengthened,
catchability is not improved so much Regulations regarding such fishing sub-gear is
necessary to avoid excessive competitions among fishermen.
Possible Measures for Fisheries Management (Total Catch by Species)
Stemming from the international law of the sea, as of November 1993, a country may set a total allowable catch (TAC) of the total catch by species as its upper limit.
Other countries, therefore, may only catch the difference between the TAC and actual catches, thus limiting the catches beyond the TAC.
Catch quota system is also one of the methods of restriction of the catches.
Possible Measures for Fisheries Management (Boat and Operation)
Capacity for Number of Fishing Boats and Duration of Fishing Operations
Many fishing activities are regulated by a licensing system
This is direct control on the level of exploitation Because, catches can be significantly increased
when there is an increase in efficiency and operation frequencies
Fundamentals of Fisheries Resource Management
Thank You