The return period is useful for risk analysis when trying to estimate the probability that the value of an extreme variable will be exceeded, possibly leading to the failure of a structure designed for a given event.

To make the relationship evident, it is assumed that the occurrence of the different events is not correlated, that is: the probability of occurrence of an event is independent of the other events. Under this assumption we have that if the probability of occurrence of an event of a certain magnitude or greater during a period of time is , then the probability that an event of greater magnitude does not occur in this period of time is , and since the probabilities are independent from one period to another, then the probability that such an event does not occur during consecutive periods is the multiplication of the individual probabilities, that is, . Finally, the probability that an event of this magnitude or greater occurs at least once during these periods is , this probability is defined as the risk (that the work will be exceeded by the magnitude of the event) and therefore:.

where:.

It is the expression that relates the return period to the probability of occurrence of an event of a given magnitude or greater in a period.

From the equation shown below you can obtain the probability that an event with a certain return period will happen within the following time periods; For example, the probability that a 100-year return period flood will occur during the next 100 years is or .

Contenido

El período de retorno es uno de los parámetros más significativos a ser tomado en cuenta en el momento de dimensionar una obra hidráulica destinada a soportar avenidas, como por ejemplo: el vertedero o aliviadero de una presa, obras que crucen sobre corrientes de agua, etc.

En hidrología es frecuente considerar zona inundable a aquella que es cubierta por las aguas en tormentas de hasta quinientos años de periodo de retorno. Esto significa que la cantidad de lluvia caída en un solo día para ese periodo de retorno solamente se iguala o supera, estadísticamente, una vez cada 500 años. En términos numéricos se expresa que la probabilidad de que se presente una precipitación "Precipitación (meteorología)") de tal magnitud o superior en un determinado año es p = 1/500 = 0.002 = 0.2%; o bien, la probabilidad de que no se presente es la complementaria, 1 - p = 0.998 = 99,8%. Sin embargo, eso no implica que no puedan producirse dos tormentas de intensidad igual o superior a la de 500 años en dos años consecutivos; pero en promedio será una vez cada 500 años.

En general, si un evento tiene un periodo de retorno de t años, el número medio de eventos que estadísticamente pueden presentarse en un año determinado es:.

Algunos de los períodos de retorno generalmente aceptados son los siguientes:.

• - Obras hidráulicas para canalización de aguas de lluvia en ciudades de tamaño de mediano a grande: de 20 a 50 años.

• - Obras hidráulicas para canalización de aguas de lluvia en ciudades pequeñas: de 5 a 10 años;.

• - Puentes de carretera: entre 50 y 500 años.

• - Aliviaderos o vertederos para presas con poblaciones aguas abajo: entre 1.000 y 10 000 años.

Hazen method

According to Hazen,[3]​ the distribution of maximum annual flows from the records of a watercourse is distributed in a logarithmic representation, according to the Gaussian normal frequency distribution. With this, from the flow records of a watercourse, a series of annual maximums can be organized, showing them in descending order, with their order numbers, from which the recurrence periods are calculated using the following expression:

The probability P that a flow rate is equal to or greater than a given value can be established by the expression:.

• - The return period does not take into account, most of the time, the variations or modifications of the channel, flow, hydrographic basin, infrastructure works, soil intervention, communication routes (bridges, railways, roads, etc.) due to causes that occurred during said period that are unrelated to the meteorological causes of the floods and that are very difficult to evaluate and completely separate from the occurrence of the floods. Furthermore, on many occasions, the occurrence of floods are attributed to unreal or pseudoscientific reasons (El Niño Phenomenon, cold drop, polar vortex, etc.) in order to avert responsibilities for poorly planned works in the fields of engineering, architecture and space organization.

• - It is not about basing the return period only on statistical or mathematical models, but also taking into account the political implications that, in turn, often have strong consequences on the almost always misnamed natural disasters, as in the cases of the Valencia flood in 1957 in Spain, the Vargas landslides in 1999, the Vargas and Mocotíes Tragedy in 2005 in Venezuela, the Missouri floods in the American Midwest in the 2011, as well as the recent ones that occurred in the Orinoco basin and its tributaries such as the Arauca, Apure and others also in Venezuela, which should be studied very carefully to obtain valid and useful conclusions.

• - Statistics.

• - Flood.

• - River dynamics.

Literature

• - (in Portuguese) Water Resources Engineering. Ray K. Linsley & Joseph B. Franzini. Editora da Universidade de Säo Paulo e Editora McGraw-Hill do Brasil, Ltda. 1978. 798 p. (see pages 148 et seq.).

External links

• - Definition of Return Period.

• - Design value of the return period.

• - Rain.

The return period is useful for risk analysis when trying to estimate the probability that the value of an extreme variable will be exceeded, possibly leading to the failure of a structure designed for a given event.

To make the relationship evident, it is assumed that the occurrence of the different events is not correlated, that is: the probability of occurrence of an event is independent of the other events. Under this assumption we have that if the probability of occurrence of an event of a certain magnitude or greater during a period of time is , then the probability that an event of greater magnitude does not occur in this period of time is , and since the probabilities are independent from one period to another, then the probability that such an event does not occur during consecutive periods is the multiplication of the individual probabilities, that is, . Finally, the probability that an event of this magnitude or greater occurs at least once during these periods is , this probability is defined as the risk (that the work will be exceeded by the magnitude of the event) and therefore:.

where:.

It is the expression that relates the return period to the probability of occurrence of an event of a given magnitude or greater in a period.

From the equation shown below you can obtain the probability that an event with a certain return period will happen within the following time periods; For example, the probability that a 100-year return period flood will occur during the next 100 years is or .

Contenido

El período de retorno es uno de los parámetros más significativos a ser tomado en cuenta en el momento de dimensionar una obra hidráulica destinada a soportar avenidas, como por ejemplo: el vertedero o aliviadero de una presa, obras que crucen sobre corrientes de agua, etc.

En hidrología es frecuente considerar zona inundable a aquella que es cubierta por las aguas en tormentas de hasta quinientos años de periodo de retorno. Esto significa que la cantidad de lluvia caída en un solo día para ese periodo de retorno solamente se iguala o supera, estadísticamente, una vez cada 500 años. En términos numéricos se expresa que la probabilidad de que se presente una precipitación "Precipitación (meteorología)") de tal magnitud o superior en un determinado año es p = 1/500 = 0.002 = 0.2%; o bien, la probabilidad de que no se presente es la complementaria, 1 - p = 0.998 = 99,8%. Sin embargo, eso no implica que no puedan producirse dos tormentas de intensidad igual o superior a la de 500 años en dos años consecutivos; pero en promedio será una vez cada 500 años.

En general, si un evento tiene un periodo de retorno de t años, el número medio de eventos que estadísticamente pueden presentarse en un año determinado es:.

Algunos de los períodos de retorno generalmente aceptados son los siguientes:.

• - Obras hidráulicas para canalización de aguas de lluvia en ciudades de tamaño de mediano a grande: de 20 a 50 años.

• - Obras hidráulicas para canalización de aguas de lluvia en ciudades pequeñas: de 5 a 10 años;.

• - Puentes de carretera: entre 50 y 500 años.

• - Aliviaderos o vertederos para presas con poblaciones aguas abajo: entre 1.000 y 10 000 años.

Hazen method

According to Hazen,[3]​ the distribution of maximum annual flows from the records of a watercourse is distributed in a logarithmic representation, according to the Gaussian normal frequency distribution. With this, from the flow records of a watercourse, a series of annual maximums can be organized, showing them in descending order, with their order numbers, from which the recurrence periods are calculated using the following expression:

The probability P that a flow rate is equal to or greater than a given value can be established by the expression:.

• - The return period does not take into account, most of the time, the variations or modifications of the channel, flow, hydrographic basin, infrastructure works, soil intervention, communication routes (bridges, railways, roads, etc.) due to causes that occurred during said period that are unrelated to the meteorological causes of the floods and that are very difficult to evaluate and completely separate from the occurrence of the floods. Furthermore, on many occasions, the occurrence of floods are attributed to unreal or pseudoscientific reasons (El Niño Phenomenon, cold drop, polar vortex, etc.) in order to avert responsibilities for poorly planned works in the fields of engineering, architecture and space organization.

• - It is not about basing the return period only on statistical or mathematical models, but also taking into account the political implications that, in turn, often have strong consequences on the almost always misnamed natural disasters, as in the cases of the Valencia flood in 1957 in Spain, the Vargas landslides in 1999, the Vargas and Mocotíes Tragedy in 2005 in Venezuela, the Missouri floods in the American Midwest in the 2011, as well as the recent ones that occurred in the Orinoco basin and its tributaries such as the Arauca, Apure and others also in Venezuela, which should be studied very carefully to obtain valid and useful conclusions.

• - Statistics.

• - Flood.

• - River dynamics.

Literature

• - (in Portuguese) Water Resources Engineering. Ray K. Linsley & Joseph B. Franzini. Editora da Universidade de Säo Paulo e Editora McGraw-Hill do Brasil, Ltda. 1978. 798 p. (see pages 148 et seq.).

External links

• - Definition of Return Period.

• - Design value of the return period.

• - Rain.