Patrones de Organización de un Párrafo

A telescope is an instrument designed to aid the observation of remote objects by collecting some form of electromagnetic radiation (such as visible light). The first known practical telescopes were invented in the Netherlands at the beginning of the 17th century. The word telescope can refer to a wide range of instruments detecting different regions of the electromagnetic spectrum. The word "telescope" (from the Greek τῆλε, tele "far" and σκοπεῖν, skopein "to look or see"; τηλεσκόπος, teleskopos "far-seeing") was coined in 1611 by the Greek mathematician Giovanni Demisiani for one of Galileo Galilei's instruments presented at a banquet at the Accademia dei Lincei. In the Starry Messenger Galileo had used the term "perspicillum". The earliest evidence of working telescopes were the refracting telescopes that appeared in the Netherlands in 1608. Their development is credited to three individuals: Hans Lippershey and Zacharias Janssen, who were spectacle makers in Middelburg, and Jacob Metius of Alkmaar.Galileo greatly improved upon these designs the following year. The idea that the objective, or light-gathering element, could be a mirror instead of a lens was being investigated soon after the invention of the refracting telescope. The potential advantages of using parabolic mirrors—reduction of spherical aberration and no chromatic aberration—led to many proposed designs and several attempts to build reflecting telescopes.In 1668, Isaac Newton built the first practical reflecting telescope, which bears his name, the Newtonian reflector. The invention of the achromatic lens in 1733 partially corrected color aberrations present in the simple lens and enabled the construction of shorter, more functional refracting telescopes. Reflecting telescopes, though not limited by the color problems seen in refractors, were hampered by the use of fast tarnishing speculum metal mirrors employed during the 18th and early 19th century—a problem alleviated by the introduction of silver coated glass mirrors in 1857,and aluminized mirrors in 1932. The maximum physical size limit for refracting telescopes is about 1 meter (40 inches), dictating that the vast majority of large optical researching telescopes built since the turn of the 20th century have been reflectors. The largest reflecting telescopes currently have objectives larger than 10 m. El parrafo trata de la invencion del telescopio y de la evolucion en el tiempo.

Técnicas de lectura: predicción, scanning y skimming

Libya unrest: Scores killed in Benghazi 'massacre'

Details have emerged of huge casualty figures in the Libyan city of Benghazi, where troops have launched a brutal crackdown on protesters. More than 200 people are known to have died, doctors say, with 900 injured. The most bloody attacks were reported over the weekend, as funeral marches were said to have come under machine-gun and heavy weapons fire. One doctor, speaking amid the sound of fresh gunfire on Sunday, told the BBC that "a real massacre" had happened.

Human Rights Watch says at least 173 people have been killed in Libya since demonstrations began on Wednesday. Benghazi, the country's second city, has been a leading focus of protests against four decades of rule by Col Muammar Gaddafi. Western politicians condemned the violence in Libya. During a phone conversation with Col Gaddafi's son, Saif al-Islam, UK Foreign Secretary William Hague spoke of London's "grave concern" at the escalation of violence, a statement said.

Libya's actions were "unacceptable and would result in worldwide condemnation", Mr Hague said. The US state department said it was "gravely concerned with disturbing reports and images coming out of Libya". "We are working to ascertain the facts, but we have received multiple credible reports that hundreds of people have been killed and injured in several days of unrest - and the full extent of the death toll is unknown due to the lack of access of international media and human rights organisations," spokesperson Philip Crowley said in a statement. Mr Crowley said the US had raised their concerns with Libyan officials, including Foreign Minister Musa Kusa. France was "extremely worried" by events in Libya, Minister for European Affairs Laurent Wauquiez said, criticising Tripoli for a "totally disproportionate" use of force. But Libya has also tried to use its leverage with the European Union, warning Brussels it could suspend co-operation against illegal migration if the EU encourages pro-democracy protests.

'Tense and scary' In a rare public admission of the unrest in Benghazi, Libyan state TV said on Sunday that an "armed people's base" in the city had come under attack and had its walls breached. That news emerged as anti-Gaddafi activists on Twitter reported that a barracks in Benghazi had "fallen". There was no way to confirm that report. Libya is one of several countries in the region to have seen pro-democracy campaigns since the fall of long-time Tunisian President Zine al-Abidine Ben Ali in January. Egypt's Hosni Mubarak was forced from power on 11 February. BBC Middle East correspondent Jon Leyne says the unrest in Libya is the most serious challenge yet to Col Gaddafi.

Libyan authorities have imposed severe media restrictions. Foreign media are largely absent from the country and internet traffic from Libya has been throttled in recent days, web analysts report. Libyan activists opposed to Col Gaddafi, as well as Libyans operating from outside the country, are using social networks Twitter and Facebook and video-sharing site YouTube to share information and images of the protests. But much of their information is extremely difficult to verify. Activists say they are reluctant to provide specific details of new protest locations in case security forces decide to attack their rallies. Reports are beginning to emerge of protests in the capital, Tripoli, but information is scarce and difficult to confirm.

One woman, who gave her name as Sara, told the BBC the situation in the city was "very tense and very scary". "Tripoli is very important, it's got people from all over Libya. Everybody's watching and waiting. Gaddafi makes us sick. This is a war," she said.

• De acuerdo al título y la imagen: ¿cuál cree usted que es el tópico que está a punto de leer? Sobre las masacres ocurridas en Libia y la revuelta popular ocurrida contra el régimen de Gaddafi

• ¿Cuál es la idea general del texto? La cantidad de muertos que se contabilizan en Libia, ya que se conocen cifras oficiales, que apuntan a 200 muertos posteriores a la represión a las manifestaciones, y un saldo de aproximadamente 900 personas heridas.

• ¿Que palabras se repiten? Violence Killed Injured Unrest • ¿Que palabras se parecen al español? Emerged Figures Troops Brutal Protesters Reported Massacre Human Difficult

• ¿Cuales son las palabras en negrita, el titulo, subtitulo o gráficos que te ayudan a entender el texto? Unrest Killed Massacre

• ¿De qué trata el texto? Lee el primer párrafo y el último o la ultimas ideas del último párrafo. Luego de los ataques represivos realizados por las fuerzas leales a Gadaffi, se pudieron conocer la cifra de muertos y heridos, lo cual ha generado alarma en todas las instancias de la comunidad internacional ya que se están violando los derechos humanos de los manifestantes y violándoles el derecho a la disidencia.

UNIDAD IV TALLER

El siguiente trabajo fue realizado en equipo, en compañia de los compañeros, Lenmar Badell, Rafael Riera, Alejandro Castro y Carlos Martinez. Metals Marcadores de definición: A metal is a chemical element that is a good conductor of both electricity and heat and forms cations and ionic bonds with non-metals. In chemistry, a metal (from Greek "μέταλλον" – métallon, "mine") is an element, compound, or alloy characterized by high electrical conductivity. In a metal, atoms readily lose electrons to form positive ions (cations). Those ions are surrounded by delocalized electrons, which are responsible for the conductivity. The solid thus produced is held by electrostatic interactions between the ions and the electron cloud, which are called metallic bonds. Definition Metals are sometimes described as an arrangement of positive ions surrounded by a sea of delocalized electrons. They are one of the three groups of elements as distinguished by their ionization and bonding properties, along with the metalloids and non-metals. Metals occupy the bulk of the periodic table, while non-metallic elements can only be found on the right-hand-side of the Periodic Table of the Elements. A diagonal line, drawn from boron (B) to polonium (Po), separates the metals from the nonmetals. Most elements on this line are metalloids, sometimes called semiconductors. This is because these elements exhibit electrical properties common to both conductors and insulators. Elements to the lower left of this division line are called metals, while elements to the upper right of the division line are called nonmetals. An alternative definition of metal refers to the band theory. If one fills the energy bands of a material with available electrons and ends up with a top band partly filled then the material is a metal. This definition opens up the category for metallic polymers and other organic metals, which have been made by researchers and employed in high-tech devices. These synthetic materials often have the characteristic silvery gray reflectiveness (luster) of elemental metals. Using Metals in Astronomy In the specialized usage of astronomy and astrophysics, the term "metal" is often used to refer collectively to all elements other than hydrogen or helium, including substances as chemically non-metallic as neon, fluorine, and oxygen. Nearly all the hydrogen and helium in the Universe was created in Big Bang nucleosynthesis, whereas all the "metals" were produced by nucleosynthesis in stars or supernovae. The Sun and the Milky Way Galaxy are composed of roughly 74% hydrogen, 24% helium, and 2% "metals" (the rest of the elements; atomic numbers 3–118) by mass.[3] The concept of a metal in the usual chemical sense is irrelevant in stars, as the chemical bonds that give elements their properties cannot exist at stellar temperatures. Palabras de definicion: is, are, discribed as, this is, refers to, is a, was. Idea principal del texto: El texto explica la deficion de los metales, se muestran sus elementos y como esta compuesta esa aleacion, asi como tambien el uso quese le puede dar en la astronomia. Marcadores de tiempo: HISTORY OF MOBILE PHONES An evolution of mobile phones Radiophones have a long and varied history going back to Reginald Fessenden's invention and shore-to-ship demonstration of radio telephony, through the Second World War with military use of radio telephony links and civil services in the 1950s. The first mobile telephone call made from a car occurred in St. Louis, Missouri, USA on June 17, 1946, using the Bell System's Mobile Telephone Service, but the system was impractical from what is considered a portable handset today. The equipment weighed 80 pounds (36 kg), and the AT&T service, basically a massive party line, cost $30 USD per month (equal to $337.33 today) plus $.30 to $.40 per local call, equal to $3.37 to $4.5 today. In 1960, the world’s first partly automatic car phone system, Mobile System A (MTA), was launched in Sweden. MTA phones were composed of vacuum tubes and relays, and had a weight of 40 kg. In 1962, a more modern version called Mobile System B (MTB) was launched, which was a push-button telephone, and which used transistors in order to enhance the telephone’s calling capacity and improve its operational reliability. In 1971, the MTD version was launched, opening for several different brands of equipment and gaining commercial success. Martin Cooper, a Motorola researcher and executive is considered to be the inventor of the first practical mobile phone for handheld use in a non-vehicle setting, after a long race against Bell Labs for the first portable mobile phone. Using a modern, if somewhat heavy portable handset, Cooper made the first call on a handheld mobile phone on April 3, 1973 to his rival, Dr. Joel S. Engel of Bell Labs. The first commercially automated cellular network (the 1G generation) was launched in Japan by NTT in 1979, initially in the metropolitan area of Tokyo. Within five years, the NTT network had been expanded to cover the whole population of Japan and became the first nationwide 1G network. In 1981, this was followed by the simultaneous launch of the Nordic Mobile Telephone (NMT) system in Denmark, Finland, Norway and Sweden. In 2001, the first commercial launch of 3G (Third Generation) was again in Japan by NTT DoCoMo on the WCDMA standard. Mobile phones generally obtain power from rechargeable batteries. There are a variety of ways used to charge cell phones, including USB, portable batteries, mains power (using an AC adapter), cigarette lighters (using an adapter), or a dynamo. In 2009, the first wireless charger was released for consumer use. On 17 February 2009, the GSM Association (GSMA), together with 17 mobile phone manufacturers and providers, announced[16] their commitment to implementing a cross-industry standard for a universal charging solution for new mobile phones. In October 2009, the International Telecommunication Union (ITU) announced that it had also embraced the Universal Charging Solution standard - based on the OMTP specifications promoted by the GSMA - as its "energy-efficient one-charger-fits-all new mobile phone solution," and added: "Based on the Micro-USB interface, UCS chargers will also include a 4-star or higher efficiency rating — up to three times more energy-efficient than an unrated charger."[19] In 2009, many mobile phone manufacturers signed a Memorandum of Understanding (MoU), agreeing to make most new data-enabled cell phones marketed in the EU compatible with a common External Power Supply (EPS). In 2006, the People's Republic of China issued a standard for mobile device power supplies (based on a 5V Power Supply with a USB-A receptacle and a detachable cable). The 2006 regulation is flexible regarding the interface on the mobile phone itself, allowing for the use of adapter cables if the mobile device is not equipped with a standard USB connector. The standard was revised in December, 2009 (CCSA YD/T 1591-2006 updated to YD/T 1591-2009).

UNIDAD IV (ACTIVIDAD REALIZADA EN CLASES)

El siguiente trabajo fue realizado en equipo, en compañia de los compañeros, Lenmar Badell, Rafael Riera, Alejandro Castro y Carlos Martinez. Metals Marcadores de definición: A metal is a chemical element that is a good conductor of both electricity and heat and forms cations and ionic bonds with non-metals. In chemistry, a metal (from Greek "μέταλλον" – métallon, "mine"[1]) is an element, compound, or alloy characterized by high electrical conductivity. In a metal, atoms readily lose electrons to form positive ions (cations). Those ions are surrounded by delocalized electrons, which are responsible for the conductivity. The solid thus produced is held by electrostatic interactions between the ions and the electron cloud, which are called metallic bonds.[2] Definition Metals are sometimes described as an arrangement of positive ions surrounded by a sea of delocalized electrons. They are one of the three groups of elements as distinguished by their ionization and bonding properties, along with the metalloids and non-metals. Metals occupy the bulk of the periodic table, while non-metallic elements can only be found on the right-hand-side of the Periodic Table of the Elements. A diagonal line, drawn from boron (B) to polonium (Po), separates the metals from the nonmetals. Most elements on this line are metalloids, sometimes called semiconductors. This is because these elements exhibit electrical properties common to both conductors and insulators. Elements to the lower left of this division line are called metals, while elements to the upper right of the division line are called nonmetals. An alternative definition of metal refers to the band theory. If one fills the energy bands of a material with available electrons and ends up with a top band partly filled then the material is a metal. This definition opens up the category for metallic polymers and other organic metals, which have been made by researchers and employed in high-tech devices. These synthetic materials often have the characteristic silvery gray reflectiveness (luster) of elemental metals. Using Metals in Astronomy In the specialized usage of astronomy and astrophysics, the term "metal" is often used to refer collectively to all elements other than hydrogen or helium, including substances as chemically non-metallic as neon, fluorine, and oxygen. Nearly all the hydrogen and helium in the Universe was created in Big Bang nucleosynthesis, whereas all the "metals" were produced by nucleosynthesis in stars or supernovae. The Sun and the Milky Way Galaxy are composed of roughly 74% hydrogen, 24% helium, and 2% "metals" (the rest of the elements; atomic numbers 3–118) by mass.[3] The concept of a metal in the usual chemical sense is irrelevant in stars, as the chemical bonds that give elements their properties cannot exist at stellar temperatures. Palabras de definicion: is, are, discribed as, this is, refers to, is a, was. Idea principal del texto: El texto explica la deficion de los metales, se muestran sus elementos y como esta compuesta esa aleacion, asi como tambien el uso quese le puede dar en la astronomia. Marcadores de tiempo: HISTORY OF MOBILE PHONES An evolution of mobile phones Radiophones have a long and varied history going back to Reginald Fessenden's invention and shore-to-ship demonstration of radio telephony, through the Second World War with military use of radio telephony links and civil services in the 1950s. The first mobile telephone call made from a car occurred in St. Louis, Missouri, USA on June 17, 1946, using the Bell System's Mobile Telephone Service, but the system was impractical from what is considered a portable handset today. The equipment weighed 80 pounds (36 kg), and the AT&T service, basically a massive party line, cost $30 USD per month (equal to $337.33 today) plus $.30 to $.40 per local call, equal to $3.37 to $4.5 today. In 1960, the world’s first partly automatic car phone system, Mobile System A (MTA), was launched in Sweden. MTA phones were composed of vacuum tubes and relays, and had a weight of 40 kg. In 1962, a more modern version called Mobile System B (MTB) was launched, which was a push-button telephone, and which used transistors in order to enhance the telephone’s calling capacity and improve its operational reliability. In 1971, the MTD version was launched, opening for several different brands of equipment and gaining commercial success. Martin Cooper, a Motorola researcher and executive is considered to be the inventor of the first practical mobile phone for handheld use in a non-vehicle setting, after a long race against Bell Labs for the first portable mobile phone. Using a modern, if somewhat heavy portable handset, Cooper made the first call on a handheld mobile phone on April 3, 1973 to his rival, Dr. Joel S. Engel of Bell Labs.[7] The first commercially automated cellular network (the 1G generation) was launched in Japan by NTT in 1979, initially in the metropolitan area of Tokyo. Within five years, the NTT network had been expanded to cover the whole population of Japan and became the first nationwide 1G network. In 1981, this was followed by the simultaneous launch of the Nordic Mobile Telephone (NMT) system in Denmark, Finland, Norway and Sweden. In 2001, the first commercial launch of 3G (Third Generation) was again in Japan by NTT DoCoMo on the WCDMA standard. Mobile phones generally obtain power from rechargeable batteries. There are a variety of ways used to charge cell phones, including USB, portable batteries, mains power (using an AC adapter), cigarette lighters (using an adapter), or a dynamo. In 2009, the first wireless charger was released for consumer use. On 17 February 2009, the GSM Association (GSMA), together with 17 mobile phone manufacturers and providers, announced[16] their commitment to implementing a cross-industry standard for a universal charging solution for new mobile phones. In October 2009, the International Telecommunication Union (ITU) announced that it had also embraced the Universal Charging Solution standard - based on the OMTP specifications promoted by the GSMA - as its "energy-efficient one-charger-fits-all new mobile phone solution," and added: "Based on the Micro-USB interface, UCS chargers will also include a 4-star or higher efficiency rating — up to three times more energy-efficient than an unrated charger."[19] In 2009, many mobile phone manufacturers signed a Memorandum of Understanding (MoU), agreeing to make most new data-enabled cell phones marketed in the EU compatible with a common External Power Supply (EPS). In 2006, the People's Republic of China issued a standard for mobile device power supplies (based on a 5V Power Supply with a USB-A receptacle and a detachable cable). The 2006 regulation is flexible regarding the interface on the mobile phone itself, allowing for the use of adapter cables if the mobile device is not equipped with a standard USB connector.[23] The standard was revised in December, 2009 (CCSA YD/T 1591-2006 updated to YD/T 1591-2009).

UNIDAD IV (ACTIVIDAD REALIZADA EN CLASES)

Types of waste TALLER UNIDAD I y II

Types of waste
While the elimination of waste may seem like a simple and clear subject it is noticeable that waste is often very conservatively identified. This then hugely reduces the potential of such an aim. The elimination of waste is the goal of Lean, and Toyota defined three broad types of waste: muda, muri and mura; it should be noted that for many Lean implementations this list shrinks to the first waste type only with corresponding benefits decrease.
To illustrate the state of this thinking Shigeo Shingo observed that only the last turn of a bolt tightens it—the rest is just movement. This ever finer clarification of waste is key to establishing distinctions between value-adding activity, waste and non-value-adding work. Non-value adding work is waste that must be done under the present work conditions. One key is to measure, or estimate, the size of these wastes, to demonstrate the effect of the changes achieved and therefore the movement toward the goal.
The "flow" (or smoothness) based approach aims to achieve JIT, by removing the variation caused by work scheduling and thereby provide a driver, rationale or target and priorities for implementation, using a variety of techniques. The effort to achieve JIT exposes many quality problems that are hidden by buffer stocks; by forcing smooth flow of only value-adding steps, these problems become visible and must be dealt with explicitly. Muri is all the unreasonable work that management imposes on workers and machines because of poor organization, such as carrying heavy weights, moving things around, dangerous tasks, even working significantly faster than usual. It is pushing a person or a machine beyond its natural limits.
This may simply be asking a greater level of performance from a process than it can handle without taking shortcuts and informally modifying decision criteria. Unreasonable work is almost always a cause of multiple variations. To link these three concepts is simple in TPS and thus Lean. Firstly, muri focuses on the preparation and planning of the process, or what work can be avoided proactively by design. Next, mura then focuses on how the work design is implemented and the elimination of fluctuation at the scheduling or operations level, such as quality and volume. Muda is then discovered after the process is in place and is dealt with reactively. It is seen through variation in output. It is the role of management to examine the muda, in the processes and eliminate the deeper causes by considering the connections to the muri and mura of the system. The muda and mura inconsistencies must be fed back to the muri, or planning, stage for the next project.
A typical example of the interplay of these wastes is the corporate behaviour of "making the numbers" as the end of a reporting period approaches. Demand is raised to 'make plan,' increasing (mura), when the "numbers" are low, which causes production to try to squeeze extra capacity from the process, which causes routines and standards to be modified or stretched. This stretch and improvisation leads to muri-style waste, which leads to downtime, mistakes and back flows, and waiting, thus the muda of waiting, correction and movement.

A. Categorias lexicales y uso del diccionario.
1. Selecciona un texto relacionado con tu area de interes. Identifica 3 palabras que no conoces.. agrega las abreviaciones.
Avoided: avoid / verbo transitivo ‹obstacle/place› evitar; (N) [Función] Stretched /stret/ verbo transitivo ‹arm/leg› estirar, extender (conj.⇒); (N) [Función] Beyond / preposición / más allá de / (N) [Función]
2. Idea principal del texto (en español)
Los desperdicios como problema de todas las industrias generan innumerables problemas, por lo tanto es de vital importancia implementar técnicas de ingeniería como la manufactura magra para eliminar todos los tipos de desperdicios.
3. Categorias lexicales: (2 ejemplos por categoria)
Palabras de contenido:
Palabras de Función: to, then
Verbos: reduces, achieve
Adverbio: conservatively, explicitly
Adjetivo: heavy, dangerous
Artículo: the, an
Preposiciones: with, like
Conjunción: Because, for
Cognados verdaderos: potential, demonstrate
Cognados Falsos:
Sufijo: unreasonable, performance
Prefijos: unreasonable

1.The muda and mura inconsistencies must be fed back to the muri, or planning, stage for the next project.
FN: The muda and mura inconsistencies
PRE: The muda and mura
NUCLEO: inconsistencies
FV: must be fed back to the muri, or planning, stage for the next project.
NUCLEO: be
Tiempo verbal: Presente.

2. This ever finer clarification of waste is key to establishing distinctions between value-adding activity, waste and non-value-adding work.
FN: This ever finer clarification of waste
PRE: This ever finer
POST: of waste
NUCLEO: clarification
FV: is key to establishing distinctions between value-adding activity, waste and non-value-adding work.
NUCLEO: is
Tiempo verbal: presente simple

UNIDAD I

Unidad 1. Uso apropiado del Diccionario

En esta unidad se usara apropiadamente el diccionario bilingüe y monolingüe, como una habilidad de búsqueda de textos necesarios para la comprensión de párrafos en inglés.

1. Ejercicio:

En esta unidad se usara apropiadamente el diccionario bilingüe y monolingüe, como una habilidad de búsqueda de textos necesarios para la comprensión de párrafos en inglés.

The Purpose of a Project Quality Plan

Quality can be defined as meeting the customer's expectations or exceeding the customer expectations achieved by way of deliverables and/or activitiesperformed to produce those deliverables.

Project Quality Plan can be defined as a set of activities planned at the beginningof the project that helps achieve Quality in the Project being executed. ThePurpose of the Project Quality Plan is to define these activities / tasks that intends to deliver products while focussing on achieveing customer's quality expectations. These activities / tasks are defined on the basis of the quality standards set by the organization delivering the product.

Project Quality Plan identifies which Quality Standards are relevant to the project and determines how can they be satisfied. It includes the implementation of Quality Events (peer reviews, checklist execution) by using various Quality Materials (templates, standards, checklists) available within the organization.Theholding of the Quality Event is termed as Quality Control. As an output of thevarious activities, Quality Metrics or Measurements are captured which assist incontinuous improvement of Quality thus adding to the inventory of Lessons Learned. Quality Assurance deals in preparation of the Quality Plan and formation of organization wide standards.

5 Palabras Nuevas:

· Customer: Cliente. Sust. (n) [Contenido]

· Achieved: Logrado. Sust. (v.t) [Función]

· Being: Ser. Sust. (N) [Función]

· Focussing: Enfoque. Sust. (N) [Función]

· Basis: Base. Sust. (N) [Función]

Categorías Lexicales:

Sustantivos: Customer, Being.

Adjetivos: Continuous, Wide.

Verbos: Can, Identifies.

Conjución: While, Thus.

Preposiciones: at the beginning, to define, to the inventory, to the project.

Articulos: The, a.

Prefijo:

Sufijo: available, deliverables

Cognado Falsos: Evento Event = Acontecimiento.

Cognados verdaderos: Activities = Actividades, Project =Proyecto, Products = Productos.

Idea Principal Del Texto

El texto seleccionado abarca información referente al propósito de un plan de calidad para un proyecto de entregas, donde calidad es definida como satisfacer las necesidades del cliente o superar sus expectativas en cuanto a entregas o actividades realizadas para producir dichas entregas, por otro lado se explica el plan de calidad como el conjunto de actividades previstas en el comienzo del proyecto que ayuda a lograr la calidad del mismo para el momento de su ejecución, y el propósito del proyecto es definir cada actividad o tarea que tiene la intención de entregar productos, mientras que logran superar las expectativas de calidad de los clientes, estas actividades y tareas se definen sobre bases de las normas de calidad establecidas por la organización acerca de la entrega del producto, las normas de calidad son pertinentes para el proyecto, identifica y determina como pueden estar satisfechos los clientes, el plan incluye la ejecución de eventos de calidad, (exámenes, ejecución de la lista de comprobación) mediante el uso de diversos materiales de calidad (plantillas, normas, lista de comprobación disponibles en la organización.

Blog para INGLES INSTRUMENTAL

Solo para actividades de Ingles Instrumental.