Relationships between models and data in growing poultry.

IF 1.7 3区农林科学 Q2 AGRICULTURE, DAIRY & ANIMAL SCIENCE

British Poultry Science Pub Date : 2025-04-16 DOI:10.1080/00071668.2025.2483733

G C Emmans, R M Gous

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引用次数: 0

Abstract

1. Three plausible rules are used to define the problem that a growth function must solve. Rule 1, growth rate, dW/dt, is a function of weight, W; Rule 2; the standard deviation of weight, σ_w, is proportional to W so that the natural log of W, lnW, rather than W should be used; Rule 3, there is an upper limit to body weight, A which represents the animal's mature weight.2. Applying the rules identifies a problem: how is the rate of change in lnW over time, dlnW/dt, related to lnW? The problem is solved by using Rule 4, which is to make the relationship as simple as possible. The solution is a form of the Gompertz function: dlnW/dt=B.ln(A/W), where B is a parameter describing the rate of maturing.3. The following study proposed that this function sufficiently described the inherited post-hatching growth potential of domestic birds. It was used to explore whether any given data set can describe such potential at all times. It can be further used to explore errors in data collection and misreporting.4. Examples are given for tests of the function, its use in examining data for accuracy and extension to chemical and physical growth. For male broilers of the Cobb 700 strain, the mature weights (A) of protein, water, lipid and ash were 1194 g, 3984 g, 1541 g and 221 g, respectively. The common Gompertz rate parameter (B) for all four components was 0.0410/d.5. Models for the chemical body composition of broilers can provide the basis for calculating energy and amino acid requirements, responses and economically optimum feeding strategies.

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生长家禽模型与数据之间的关系。

1. 三个貌似合理的规则被用来定义生长函数必须解决的问题。规则1，增长率dW/dt是权重W的函数；规则2;权重的标准差σw与W成正比，因此应使用W的自然对数lnW，而不应使用W；规则3，有一个体重上限，A代表动物的成熟体重。应用这些规则会发现一个问题：lnW随时间的变化率dlnW/dt与lnW有什么关系？这个问题可以通过使用规则4来解决，即使关系尽可能简单。解是Gompertz函数的一种形式：dlnW/dt=B.ln(a /W)，其中B是描述成熟速率的参数。接下来的研究表明，这一功能充分描述了家禽孵化后的遗传生长潜力。它被用来探索是否任何给定的数据集都能在任何时候描述这种潜力。它可以进一步用于探索数据收集和误报中的错误。举例说明了该函数的测试，它在检查数据的准确性和扩展到化学和物理生长方面的应用。Cobb 700雄性肉鸡的蛋白质、水分、脂肪和灰分成熟重(A)分别为1194 g、3984 g、1541 g和221 g。四种组分的Gompertz速率参数(B)均为0.0410/d.5。建立肉仔鸡化学体组成模型可为计算肉仔鸡的能量和氨基酸需要量、反应和最经济的饲养策略提供依据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

British Poultry Science 农林科学-奶制品与动物科学

CiteScore

3.90

自引率

5.00%

发文量

审稿时长

4.5 months

期刊介绍： From its first volume in 1960, British Poultry Science has been a leading international journal for poultry scientists and advisers to the poultry industry throughout the world. Over 60% of the independently refereed papers published originate outside the UK. Most typically they report the results of biological studies with an experimental approach which either make an original contribution to fundamental science or are of obvious application to the industry. Subjects which are covered include: anatomy, embryology, biochemistry, biophysics, physiology, reproduction and genetics, behaviour, microbiology, endocrinology, nutrition, environmental science, food science, feeding stuffs and feeding, management and housing welfare, breeding, hatching, poultry meat and egg yields and quality.Papers that adopt a modelling approach or describe the scientific background to new equipment or apparatus directly relevant to the industry are also published. The journal also features rapid publication of Short Communications. Summaries of papers presented at the Spring Meeting of the UK Branch of the WPSA are published in British Poultry Abstracts .