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21 efficiency
n1) эффективность, действенность2) производительность, продуктивность4) умение; подготовка; квалификация
- advertising efficiency
- average efficiency
- capital efficiency
- commercial efficiency
- cost efficiency
- cumulative efficiency
- economic efficiency
- economical efficiency
- enterprise efficiency
- farm labour efficiency
- feeding efficiency
- feed-use efficiency
- feed-utilization efficiency
- high efficiency
- increased efficiency
- industrial efficiency
- investment efficiency
- irrigation efficiency
- labour efficiency
- learning efficiency
- low efficiency
- management efficiency
- manufacturing efficiency
- marginal efficiency of capital investment
- maximum efficiency
- mean efficiency
- net efficiency
- normal efficiency
- operating efficiency
- operative efficiency
- optimum efficiency
- peak efficiency
- performance efficiency
- power efficiency
- production efficiency
- productive efficiency
- relative efficiency
- statistical efficiency
- technical efficiency
- total efficiency
- working efficiency
- efficiency of capital
- efficiency of capital markets
- efficiency of cooperation
- efficiency of customer service
- efficiency of financial instruments
- efficiency of an invention
- efficiency of investments
- efficiency of labour
- efficiency of management
- efficiency of payments
- efficiency of production
- enhance efficiency
- improve efficiency
- increase efficiency
- obtain maximum efficiency
- raise efficiencyEnglish-russian dctionary of contemporary Economics > efficiency
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22 efficiency
1) экономическая эффективность; производительность; результативность; продуктивность; прибыльность2) коэффициент полезного действия, кпд; коэффициент использования3) выполнение норм выработки; коэффициент перевыполнения норм выработки4) высокий организационно-технический уровень -
23 irrigation application efficiency
Универсальный англо-русский словарь > irrigation application efficiency
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24 irrigation system efficiency
Англо-русский гидрогеологический словарь > irrigation system efficiency
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25 эффективность орошения
irrigation efficiencyБольшой англо-русский и русско-английский словарь > эффективность орошения
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26 sulama verimi
irrigation efficiency -
27 эффективность орошения
Русско-английский политехнический словарь > эффективность орошения
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28 sulama verimi
irrigation efficiency -
29 коэффициент полезного действия оросительной системы
1) Engineering: water conveyance-and-delivery efficiency2) Economy: irrigation efficiencyУниверсальный русско-английский словарь > коэффициент полезного действия оросительной системы
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30 коэффициент использования воды при поливе
1) Ecology: farm irrigation efficiency2) Makarov: field irrigation efficiencyУниверсальный русско-английский словарь > коэффициент использования воды при поливе
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31 коэффициент полезного использования воды при поливе
Универсальный русско-английский словарь > коэффициент полезного использования воды при поливе
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32 эффективность орошения
1) Engineering: irrigation efficiency2) Makarov: potential benefit of irrigationУниверсальный русско-английский словарь > эффективность орошения
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33 коэффициент полезного действия внутрихозяйственной сети
Универсальный русско-английский словарь > коэффициент полезного действия внутрихозяйственной сети
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34 коэффициент полезного действия мелкой оросительной сети
Makarov: field irrigation efficiencyУниверсальный русско-английский словарь > коэффициент полезного действия мелкой оросительной сети
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35 коэффициент полезного действия оросительной сети
Makarov: irrigation efficiencyУниверсальный русско-английский словарь > коэффициент полезного действия оросительной сети
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36 коэффициент удовлетворения потребности растений в оросительной воде
Engineering: unit irrigation efficiencyУниверсальный русско-английский словарь > коэффициент удовлетворения потребности растений в оросительной воде
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37 Agriculture
Historically, Portugal's agricultural efficiency, measured in terms of crop yields and animal productivity, has been well below that of other European countries. Agricultural inefficiency is a consequence of Portugal's topography and climate, which varies considerably from north to south and has influenced farm size and farming methods. There are three major agricultural zones: the north, center, and south. The north (the area between the Douro and Minho Rivers, including the district of Trás-os-Montes) is mountainous with a wet (180-249 cm of rainfall/year), moderately cool climate. It contains about 2 million hectares of cultivated land excessively fragmented into tiny (3-5 hectares) family-owned farms, or minifúndios, a consequence of ancient settlement patterns, a strong attachment to the land, and the tradition of subdividing land equally among family members. The farms in the north produce the potatoes and kale that are used to make caldo verde soup, a staple of the Portuguese diet, and the grapes that are used to make vinho verde (green wine), a light sparkling white wine said to aid the digestion of oily and greasy food. Northern farms are too small to benefit from mechanization and their owners too poor to invest in irrigation, chemical fertilizers, or better seeds; hence, agriculture in the north has remained labor intensive, despite efforts to regroup minifúndios to increase farm size and efficiency.The center (roughly between the Douro and the Tagus River) is bisected by the Mondego River, the land to either side of which is some of the most fertile in Portugal and produces irrigated rice, corn, grapes, and forest goods on medium-sized (about 100 hectares) farms under a mixture of owner-cultivation and sharecropping. Portugal's center contains the Estrela Mountains, where sheep raising is common and wool, milk, and cheese are produced, especially mountain cheese ( Queijo da Serra), similar to French brie. In the valley of the Dão River, a full-bodied, fruity wine much like Burgundy is produced. In the southern part of the center, where the climate is dry and soils are poor, stock raising mixes with cereal crop cultivation. In Estremadura, the area north of Lisbon, better soils and even rainfall support intensive agriculture. The small farms of this area produce lemons, strawberries, pears, quinces, peaches, and vegetables. Estremadura also produces red wine at Colares and white wine at Buçelas.The south (Alentejo and Algarve) is a vast rolling plain with a hot arid climate. It contains about 2.6 million hectares of arable land and produces the bulk of Portugal's wheat and barley. It also produces one of Portugal's chief exports, cork, which is made from bark cut from cork oaks at nine-year intervals. There are vast groves of olive trees around the towns of Elvas, Serpa, and Estremoz that provide Portugal's olives. The warm climate of the Algarve (the most southern region of Portugal) is favorable for the growing of oranges, pomegranates, figs, and carobs. Almonds are also produced. Farms in the south, except for the Algarve, are large estates (typically 1,000 hectares or more in size) known as latifúndios, worked by a landless, wage-earning rural work force. After the Revolution of 25 April 1974, these large estates were taken over by the state and turned into collective farms. During the 1990s, as the radicalism of the Revolution moderated, collectivized agriculture was seen as counterproductive, and the nationalized estates were gradually returned to their original owners in exchange for cash payments or small parcels of land for the collective farm workers.Portugal adopted the Common Agricultural Policy (CAP) when it joined the European Union (EU) in 1986. The CAP, which is based on the principles of common pricing, EU preferences, and joint financing, has shifted much of Portugal's agricultural decision making to the EU. Under the CAP, cereals and dairy products have experienced declines in prices because these are in chronic surplus within the EU. Alentejo wheat production has become unprofitable because of poor soils. However, rice, tomatoes, sunflower, and safflower seed and potatoes, as well as Portuguese wines, have competed well under the CAP system. -
38 rate
3) частота4) расход5) норма || нормировать6) тариф || тарифицировать7) степень8) отношение; коэффициент10) оценка || оценивать11) определять; устанавливать; подсчитывать; рассчитывать (напр. мощность, несущую способность)•rates to consumers — тарифы на отпуск (напр. электроэнергии) потребителям-
absolute disintegrate rate
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absorbed dose rate
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acceptance rate
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accident rate
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adiabatic lapse rate
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advance rate
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aging rate
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allowable leak rate
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angular rate
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annual depletion rate
-
application rate
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area rate
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arrival rate
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ascensional rate
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assessed failure rate
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attenuation rate
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autoconvective lapse rate
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base wage rate
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baud rate
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bearer rate
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beating rate
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bit rate
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bit-error rate
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bit-transfer rate
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block meter rate
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block-error rate
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boiling rate
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boil-up rate
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bonus rate
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break flow rate
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breeding rate
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burning rate
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calling rate
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capture rate
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carbonization rate
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cargo rate
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carrier-ionization rate
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casting rate
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catalyst circulation rate
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charging rate
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chipping rate
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chip rate
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chopping rate
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circulation rate
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class rate
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climb rate
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clock rate
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closed rate
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closure rate
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coke rate
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cold storage rates
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collision rate
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combustion rate
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completion rate
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concentration rate
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containment leak rate
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continuous rate
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controlled rate
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convective expansion rate
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conversion rate
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conveyance rate
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cooling rate
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core heat generation rate
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corrosion rate
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counting rate
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crack growth rate
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creep rate
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crosshead rate
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cure rate
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cutter wear rate
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daily consumptive use rate
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data-transfer rate
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data rate
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decay rate
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decompression rate
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deflection rate
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deionization rate
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delivery rate
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demand cost rate
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demand rate
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deposition rate
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descent rate
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development rate
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deviation rate
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differential rate
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differentiated electricity rates
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diffusion rate
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directional rate
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discharge rate
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disposal rate
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distance rate
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dither rate
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dosage rate
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downtime rate
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drainage rate
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drawing rate
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drift rate
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drilling rate
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droop rate
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dry adiabatic lapse rate
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electricity rate
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electric rate
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energy fluence rate
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energy release rate
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entropy production rate
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entropy rate
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erasing rate
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erosion rate
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error rate
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etching rate
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etch rate
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evacuation rate
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evaporating rate
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excitation rate
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exposure rate
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failure rate
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failure-per-mile rate
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false alarm rate
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fatal accident frequency rate
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fatality rate
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fault rate
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feed rate
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field germination rate
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field-repetition rate
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fieldwide rate of recovery
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film rate
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filtering rate
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finishing rate
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fire-propagation rate
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firing rate
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fission rate
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flat rate
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flexible rates
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flicker rate
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flooding rate
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flotation rate
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flour extraction rate
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flow rate
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flush production rate
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flutter rate
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forced outgage rate
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frame rate
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frame-repetition rate
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freezing rate
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freight rate
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freight-all-kinds rates
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frequency-sweep rate
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frequency-tuning rate
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fuel rate
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functional throughput rate
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gas leak rate
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gathering rate
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generation rate
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grinding rate
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growth rate
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gyro drift rate
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half-clock rate
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hardening rate
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heat absorption rate
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heat dissipation rate
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heat generation rate
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heat rate
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heat-flow rate
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heating rate
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heat-transfer rate
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hit rate
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image refresh rate
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impact wear rate
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in-commission rate
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infiltration rate
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information rate
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injection rate
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instantaneous failure rate
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intermittent rate
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ionization rate
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irrigation rate
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iso-wear rates
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job rates
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kerma rate
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keying rate
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lapse rate
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leakage rate
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linear wear rate
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line-of-sight rate
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line-repetition rate
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liquid efflux rate
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lubrication rate
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maintenance rate
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mass flow rate
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mass wear rate
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maximum efficiency rate
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maximum permissible rate
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maximum stepping rate
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medium rate
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melting rate
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melt-off rate
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metal-removal rate
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modulation rate
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moist-adiabatic lapse rate
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NC programmed feed rate
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negative flow rate
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nucleation rate
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Nyquist rate
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obturation rate
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off-peak power rate
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operating rate
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optimal feed rate
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outgassing rate
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output rate
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overall drilling rate
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oxidation rate
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paging rate
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peak power rate
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penetration rate
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percolation rate
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phase generation rate
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phase rate
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picture-taking rate
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pitch rate
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plastic strain rate
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positive flow rate
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potential rate of evaporation
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pouring rate
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power rate
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precipitation rate
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predetermined rate
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predicted failure rate
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priming rate
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printout rate
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print rate
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production decline rate
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production rate
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projection rate
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proper feed rate
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protection rate
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pull rate
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pulldown rate
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pulse-recurrence rate
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pulse rate
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radiation rate
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radioactive decay rate
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range rate
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rapid air cut feed rate
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rapid return rate
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rate of acceleration
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rate of angular motion
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rate of attack
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rate of blowing
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rate of braking
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rate of carbon drop
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rate of convergence
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rate of crack propagation
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rate of deformation
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rate of dilution
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rate of discharge
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rate of dive
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rate of energy input
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rate of exchange
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rate of exposure
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rate of fall
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rate of film movement
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rate of gain
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rate of hole deviation change
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rate of lancing
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rate of linkage
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rate of loading
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rate of opening
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rate of plant depreciation
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rate of pulse rise
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rate of rainfall
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rate of rise
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rate of roll
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rate of sedimentation
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rate of shear
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rate of slope
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rate of stirring
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rate of surface runoff
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rate or carbon oxidation
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reactivity insertion rate
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reading rate
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read rate
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recovery rate
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recycle rate
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reflood rate
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refresh rate
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refrigeration rate
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repetition rate
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reset rate
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residential rate
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respiration rate
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retail charter rate
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retail rate
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retention rate
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rigidity rate
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rolling rate
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runout rate
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sample rate
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saturated-adiabatic lapse rate
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saturation rate
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scrap generation rate
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scrap rate
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secondary creep rate
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sectorial rate
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self-discharge rate
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setting rate
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settled production rate
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settling rate
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signaling rate
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silicon pulling rate
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slew rate
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snowmelt inflow rate
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solidification rate
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sparking rate
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specific commodity rate
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specific heat flow rate
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specific rate of flow
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specific rate of sediment transport
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specific wear rate
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spreading rate of jet
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spring rate
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squeeze rate
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standard rate
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starting rate
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steam rate
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stepping rate
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stock removal rate
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strain rate
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stress rate
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sub-Nyquist rate
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success rate
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superadiabatic lapse rate
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supply rate
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survival rate
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sweep rate
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taking rate
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tariff rate
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temperature lapse rate
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testing rate
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thermal transfer rate
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through rate
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throughput rate
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time rate of change
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time rate
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time-of-day electricity rate
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time-of-day rate
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tool-wear rate
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total mass rate
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tracking rate
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traffic flow rate
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transfer rate
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transmission rate
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transport rate
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turn rate
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turnover rate
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twenty-five ampere rate
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undetected error rate
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uniform quench rate
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unit rate
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unloading rate
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update rate
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vaporizing rate
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vitrification rate
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voidage rate
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voltage recovery rate
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volume erosion rate
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volume wear rate
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volumetric flow rate
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volumetric rate
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vulcanization rate
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water application rate
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water consumption rate
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water use rate
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wear rate
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weft insertion rate
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weight rate
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wheel removal rate
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wholesale charter rate
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wholesale rate
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withdrawal rate
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write writing rate
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write rate
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yawing rate
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yaw rate
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zero-crossing rate -
39 Bakewell, Robert
SUBJECT AREA: Agricultural and food technology[br]b. 23 May 1725 Loughborough, Englandd. 1 October 1795 Loughborough, England[br]English livestock breeder who pioneered the practice of progeny testing for selecting breeding stock; he is particularly associated with the development of the Improved Leicester breed of sheep.[br]Robert Bakewell was the son of the tenant farming the 500-acre (200 hectare) Dishley Grange Farm, near Loughborough, where he was born. The family was sufficiently wealthy to allow Robert to travel, which he began to do at an early age, exploring the farming methods of the West Country, Norfolk, Ireland and Holland. On taking over the farm he continued the development of the irrigation scheme begun by his father. Arthur Young visited the farm during his tour of east England in 1771. At that time it consisted of 440 acres (178 hectares), 110 acres (45 hectares) of which were arable, and carried a stock of 60 horses, 400 sheep and 150 other assorted beasts. Of the arable land, 30 acres (12 hectares) were under root crops, mainly turnips.Bakewell was not the first to pioneer selective breeding, but he was the first successfully to apply selection to both the efficiency with which an animal utilized its food, and its physical appearance. He always had a clear idea of the animal he wanted, travelled extensively to collect a range of animals possessing the characteristics he sought, and then bred from these towards his goal. He was aware of the dangers of inbreeding, but would often use it to gain the qualities he wanted. His early experiments were with Longhorn cattle, which he developed as a meat rather than a draught animal, but his most famous achievement was the development of the Improved Leicester breed of sheep. He set out to produce an animal that would put on the most meat in the least time and with the least feeding. As his base he chose the Old Leicester, but there is still doubt as to which other breeds he may have introduced to produce the desired results. The Improved Leicester was smaller than its ancestor, with poorer wool quality but with greatly improved meat-production capacity.Bakewell let out his sires to other farms and was therefore able to study their development under differing conditions. However, he made stringent rules for those who hired these animals, requiring the exclusive use of his rams on the farms concerned and requiring particular dietary conditions to be met. To achieve this control he established the Dishley Society in 1783. Although his policies led to accusations of closed access to his stock, they enabled him to keep a close control of all offspring. He thereby pioneered the process now recognized as "progeny testing".Bakewell's fame and that of his farm spread throughout the country and overseas. He engaged in an extensive correspondence and acted as host to all of influence in British and overseas agriculture, but it would appear that he was an over-generous host, since he is known to have been in financial difficulties in about 1789. He was saved from bankruptcy by a public subscription raised to allow him to continue with his breeding experiments; this experience may well have been the reason why he was such a staunch advocate of State funding of agricultural research.[br]Further ReadingWilliam Houseman, 1894, biography, Journal of the Royal Agricultural Society. 1–31. H.C.Parsons, 1957, Robert Bakewell (contains a more detailed account).R.Trow Smith, 1957, A History of British Livestock Husbandry to 1700, London: Routledge \& Kegan Paul.—A History of British Livestock Husbandry 1700 to 1900 (places Bakewell within the context of overall developments).M.L.Ryder, 1983, Sheep and Man, Duckworth (a scientifically detailed account which deals with Bakewell within the context of its particular subject).AP
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