Changes between Version 2 and Version 3 of EwEugGroupInfo


Ignore:
Timestamp:
2010-11-23 02:00:03 (13 years ago)
Author:
shermanl
Comment:

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  • EwEugGroupInfo

    v2 v3  
    11== 8.3 Group info == 
    2 The ''Group info'' form (''Time dynamic (Ecosim) > Input > Group info'') enables entry of the Ecosim parameters listed below. You must already have an Ecosim scenario loaded (see [wiki:EwEugEcosimMenu Ecosim menu]) before you can us this form. Each scenario can have its own set of Group info parameters. 
     2The ''Group info'' form (''Time dynamic (Ecosim) > Input > Group info'') enables entry of the Ecosim parameters listed below. You must already have an Ecosim scenario loaded (see [EwEugGettingStartedEcosim Ecosim menu]) before you can us this form. Each scenario can have its own set of Group info parameters. 
    33 
    44'''Maximum relative P/B''' 
     
    1010'''Maximum relative feeding time''' 
    1111 
    12 If prey becomes more scarce, (e.g., because predator abundance increases), their predators will have to spend more time feeding (and hence be at a greater risk to predation themselves). Use this variable to limit how much the feeding time may increase. The default is that the feeding time may at the most double, i.e., a value of 2.0. There is empirical evidence showing limits to how great a predation risk organisms are willing to take. Juveniles may for instance be found hiding at food-deprived shorelines even though suitable prey is more abundant in the pelagic zone close by. Going out to there for prey would however place the juveniles at a considerable risk of predation, and they may choose not to do so, or at least to lower the risk by limiting the time spent feeding. For more information see [wiki:EwEugForagingTimeAndPredation Foraging time and predation risk]. 
     12If prey becomes more scarce, (e.g., because predator abundance increases), their predators will have to spend more time feeding (and hence be at a greater risk to predation themselves). Use this variable to limit how much the feeding time may increase. The default is that the feeding time may at the most double, i.e., a value of 2.0. There is empirical evidence showing limits to how great a predation risk organisms are willing to take. Juveniles may for instance be found hiding at food-deprived shorelines even though suitable prey is more abundant in the pelagic zone close by. Going out to there for prey would however place the juveniles at a considerable risk of predation, and they may choose not to do so, or at least to lower the risk by limiting the time spent feeding. For more information see [EwEugForagingTimeAndPredationRisk Foraging time and predation risk]. 
    1313 
    1414'''Feeding time adjustment rate (Range: ![0,1])''' 
    1515 
    16 This factor determines how fast organisms adjust feeding times so as to stabilize consumption rate per biomass (see [wiki:EwEugForagingTimeAndPredation Foraging time and predation risk]).  Setting the value to 0.0 causes feeding time (and hence time exposed to predation risk) to remain constant, all changes in consumption per biomass then result in growth rate changes.  Setting this parameter to zero also results in simulation of compensatory growth rate responses (see [wiki:EwEugCompensatoryGrowth Compensatory growth]). Setting it to 1.0 results in fast time response, which causes reduction in vulnerability to predation rather than increased growth rate when/if food density increases. See [wiki:EwEugUsingEcosimToStudyCompensation Compensatory recruitment] for recommendations for using this parameter to create the effects of compensation in recruitment in models with multi-stanza groups. See [wiki:EwEugCompensatoryNaturalMortality Compensatory natural mortality] for recommendations for using this parameter to create the effects of compensation in natural mortality. 
     16This factor determines how fast organisms adjust feeding times so as to stabilize consumption rate per biomass (see [EwEugForagingTimeAndPredationRisk Foraging time and predation risk]).  Setting the value to 0.0 causes feeding time (and hence time exposed to predation risk) to remain constant, all changes in consumption per biomass then result in growth rate changes.  Setting this parameter to zero also results in simulation of compensatory growth rate responses (see [EwEugCompensatoryGrowth Compensatory growth]). Setting it to 1.0 results in fast time response, which causes reduction in vulnerability to predation rather than increased growth rate when/if food density increases. See [EwEugCompensatoryMechanisms Compensatory recruitment] for recommendations for using this parameter to create the effects of compensation in recruitment in models with multi-stanza groups. See [wiki:EwEugCompensatoryNaturalMortality Compensatory natural mortality] for recommendations for using this parameter to create the effects of compensation in natural mortality. 
    1717 
    1818In general we recommend that you set the feeding time to 0 for all groups, apart from, e.g., marine mammals where a value of 0.5 often seems reasonable. Explore the consequences of changing this factor. 
     
    2020'''Fraction of other mortality sensitive to changes in feeding time ![0-1]''' 
    2121 
    22 This is the proportion of the unexplained natural mortality rate (M0, 1-EE x total mortality rate) that is assumed to be sensitive to changes in feeding time.  Setting it to 0.0 causes M0 to remain constant. Setting it to a higher value causes that proportion of M0 to vary in proportion to relative time spent feeding (see feeding time factor above).  Setting nonzero value along with nonzero feeding time factor generally results in density-dependent M: as density increases, feeding time usually has to increase to maintain food consumption rate, and this increased feeding time leads to higher mortality rate. See [wiki:EwEugUsingEcosimToStudyCompensation Compensatory recruitment] for recommendations for using this parameter to create the effects of compensation in recruitment in models with multi-stanza groups. 
     22This is the proportion of the unexplained natural mortality rate (M0, 1-EE x total mortality rate) that is assumed to be sensitive to changes in feeding time.  Setting it to 0.0 causes M0 to remain constant. Setting it to a higher value causes that proportion of M0 to vary in proportion to relative time spent feeding (see feeding time factor above).  Setting nonzero value along with nonzero feeding time factor generally results in density-dependent M: as density increases, feeding time usually has to increase to maintain food consumption rate, and this increased feeding time leads to higher mortality rate. See [EwEugCompensatoryMechanisms Compensatory recruitment] for recommendations for using this parameter to create the effects of compensation in recruitment in models with multi-stanza groups. 
    2323 
    2424'''Predator effect on feeding time ![0-1]''' 
    2525 
    26 Setting a nonzero value for this parameter allows you to simulate direct response of feeding time and food consumption rate to changes in predator abundance, i.e. ‘risk sensitive foraging behaviour’.  If the value is high, it is assumed that a high proportion of the food consumption rate per biomass is ‘discretionary’, i.e., the organism will reduce target food consumption rate (and hence time exposed to predation risk) by up to this fraction if predator abundance increases, and will correspondingly increase food consumption rate if predator abundance falls below the Ecopath baseline.  Note that the feeding time adjustment rate (see above) has to be greater than zero in order to see effects from nonzero values of this parameter (effect is expressed in calculations as changes in time spent feeding with changes in predator abundance, and such changes are not implemented unless adjustment rate is greater than zero). 
     26Setting a nonzero value for this parameter allows you to simulate direct response of feeding time and food consumption rate to changes in predator abundance, i.e. 'risk sensitive foraging behaviour'.  If the value is high, it is assumed that a high proportion of the food consumption rate per biomass is 'discretionary', i.e., the organism will reduce target food consumption rate (and hence time exposed to predation risk) by up to this fraction if predator abundance increases, and will correspondingly increase food consumption rate if predator abundance falls below the Ecopath baseline.  Note that the feeding time adjustment rate (see above) has to be greater than zero in order to see effects from nonzero values of this parameter (effect is expressed in calculations as changes in time spent feeding with changes in predator abundance, and such changes are not implemented unless adjustment rate is greater than zero). 
    2727 
    2828'''Density-dependent catchability (>=1)'''