temperature controller - перевод на русский
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  3. temperature controller

temperature controller - перевод на русский

ESTIMATED TEMPERATURE OF AN ASTRONOMICAL BODY
Effective Temperature; Stellar temperature; Surface temperature (star); Solar temperature
  • The effective temperature of the [[Sun]] (5777 [[kelvin]]s) is the temperature a black body of the same size must have to yield the same total emissive power.
Найдено результатов: 689
temperature controller      

общая лексика

термореле

строительное дело

терморегулятор, регулятор температуры

temperature controller      
терморегулятор, регулятор температуры
temperature control         
PROCESS OF ADJUSTING HEAT FLUX TO MAINTAIN A SYSTEM AT A DESIRED TEMPERATURE
Temperature controll

общая лексика

непрерывное термостатирование

терморегулирование

нефтегазовая промышленность

регулирование температуры

регулятор температуры

disk controller         
CONTROLLER FOR DISK STORAGE, USUALLY INTEGRATED INTO THE DRIVE
Hard disk controller; Hard drive controller; HD controller; Drive controller

общая лексика

дисковый контроллер, контроллер диска

плата расширения и/или микросхема, обеспечивающая взаимодействие процессора с дисковым накопителем

PID controller         
  • Showing the evolution of analog control loop signaling from the pneumatic to the electronic eras
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>d</sub> (''K''<sub>p</sub> and ''K''<sub>i</sub> held constant)
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>i</sub> (''K''<sub>p</sub> and ''K''<sub>d</sub> held constant)
  • Proportional control using nozzle and flapper high gain amplifier and negative feedback
  • Effects of varying PID parameters (K<sub>p</sub>,K<sub>i</sub>,K<sub>d</sub>) on the step response of a system
  • A [[block diagram]] of a PID controller in a feedback loop. ''r''(''t'') is the desired process value or setpoint (SP), and ''y''(''t'') is the measured process value (PV).
  • PID with derivative filtering
  • PID without derivative filtering
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>p</sub> (''K''<sub>i</sub> and ''K''<sub>d</sub> held constant)
  • Basic block of a PI controller
  • alt=
  • Early PID theory was developed by observing the actions of [[helmsmen]] in keeping a vessel on course in the face of varying influences such as wind and sea state.
  • Current loops used for sensing and control signals. A modern electronic "smart" valve positioner is shown, which will incorporate its own PID controller.
CONTROL LOOP MECHANISM USED IN CONTROL ENGINEERING
PID loop; Proportional-Integral-Derivative controller; PID tuning; PID algorithm; Proportional integral derivative; PI controller; PD controller; PID control; PI Controller; Pi controller; Pidc; PID Controller; Proportional–integral–derivative controller; P.I.D. control; Droop (control); Proportional-integral-derivative controller; PID feed back controller; PID feedback controller; Three term controller; Steady-state error
ПИД-регулятор, пропорционально-интегральный (изодромный) регулятор с предварением
three term controller         
  • Showing the evolution of analog control loop signaling from the pneumatic to the electronic eras
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>d</sub> (''K''<sub>p</sub> and ''K''<sub>i</sub> held constant)
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>i</sub> (''K''<sub>p</sub> and ''K''<sub>d</sub> held constant)
  • Proportional control using nozzle and flapper high gain amplifier and negative feedback
  • Effects of varying PID parameters (K<sub>p</sub>,K<sub>i</sub>,K<sub>d</sub>) on the step response of a system
  • A [[block diagram]] of a PID controller in a feedback loop. ''r''(''t'') is the desired process value or setpoint (SP), and ''y''(''t'') is the measured process value (PV).
  • PID with derivative filtering
  • PID without derivative filtering
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>p</sub> (''K''<sub>i</sub> and ''K''<sub>d</sub> held constant)
  • Basic block of a PI controller
  • alt=
  • Early PID theory was developed by observing the actions of [[helmsmen]] in keeping a vessel on course in the face of varying influences such as wind and sea state.
  • Current loops used for sensing and control signals. A modern electronic "smart" valve positioner is shown, which will incorporate its own PID controller.
CONTROL LOOP MECHANISM USED IN CONTROL ENGINEERING
PID loop; Proportional-Integral-Derivative controller; PID tuning; PID algorithm; Proportional integral derivative; PI controller; PD controller; PID control; PI Controller; Pi controller; Pidc; PID Controller; Proportional–integral–derivative controller; P.I.D. control; Droop (control); Proportional-integral-derivative controller; PID feed back controller; PID feedback controller; Three term controller; Steady-state error

строительное дело

ПИД-регулятор, пропорционально-интегральный (изодромный) регулятор с предварением

three term controller         
  • Showing the evolution of analog control loop signaling from the pneumatic to the electronic eras
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>d</sub> (''K''<sub>p</sub> and ''K''<sub>i</sub> held constant)
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>i</sub> (''K''<sub>p</sub> and ''K''<sub>d</sub> held constant)
  • Proportional control using nozzle and flapper high gain amplifier and negative feedback
  • Effects of varying PID parameters (K<sub>p</sub>,K<sub>i</sub>,K<sub>d</sub>) on the step response of a system
  • A [[block diagram]] of a PID controller in a feedback loop. ''r''(''t'') is the desired process value or setpoint (SP), and ''y''(''t'') is the measured process value (PV).
  • PID with derivative filtering
  • PID without derivative filtering
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>p</sub> (''K''<sub>i</sub> and ''K''<sub>d</sub> held constant)
  • Basic block of a PI controller
  • alt=
  • Early PID theory was developed by observing the actions of [[helmsmen]] in keeping a vessel on course in the face of varying influences such as wind and sea state.
  • Current loops used for sensing and control signals. A modern electronic "smart" valve positioner is shown, which will incorporate its own PID controller.
CONTROL LOOP MECHANISM USED IN CONTROL ENGINEERING
PID loop; Proportional-Integral-Derivative controller; PID tuning; PID algorithm; Proportional integral derivative; PI controller; PD controller; PID control; PI Controller; Pi controller; Pidc; PID Controller; Proportional–integral–derivative controller; P.I.D. control; Droop (control); Proportional-integral-derivative controller; PID feed back controller; PID feedback controller; Three term controller; Steady-state error
ПИД-регулятор, пропорционально-интегральный (изодромный) регулятор с предварением
PID controller         
  • Showing the evolution of analog control loop signaling from the pneumatic to the electronic eras
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>d</sub> (''K''<sub>p</sub> and ''K''<sub>i</sub> held constant)
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>i</sub> (''K''<sub>p</sub> and ''K''<sub>d</sub> held constant)
  • Proportional control using nozzle and flapper high gain amplifier and negative feedback
  • Effects of varying PID parameters (K<sub>p</sub>,K<sub>i</sub>,K<sub>d</sub>) on the step response of a system
  • A [[block diagram]] of a PID controller in a feedback loop. ''r''(''t'') is the desired process value or setpoint (SP), and ''y''(''t'') is the measured process value (PV).
  • PID with derivative filtering
  • PID without derivative filtering
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>p</sub> (''K''<sub>i</sub> and ''K''<sub>d</sub> held constant)
  • Basic block of a PI controller
  • alt=
  • Early PID theory was developed by observing the actions of [[helmsmen]] in keeping a vessel on course in the face of varying influences such as wind and sea state.
  • Current loops used for sensing and control signals. A modern electronic "smart" valve positioner is shown, which will incorporate its own PID controller.
CONTROL LOOP MECHANISM USED IN CONTROL ENGINEERING
PID loop; Proportional-Integral-Derivative controller; PID tuning; PID algorithm; Proportional integral derivative; PI controller; PD controller; PID control; PI Controller; Pi controller; Pidc; PID Controller; Proportional–integral–derivative controller; P.I.D. control; Droop (control); Proportional-integral-derivative controller; PID feed back controller; PID feedback controller; Three term controller; Steady-state error

строительное дело

ПИД-регулятор, пропорционально-интегральный (изодромный) регулятор с предварением

floppy-disk controller         
  • A setup disk of Japanese [[Microsoft Office]] 4.3, provided with 3.5" 1.2&nbsp;MB and 1440&nbsp;KB formats.
CIRCUITRY THAT CONTROLS READING FROM AND WRITING TO A COMPUTER'S FLOPPY DISK DRIVE
Floppy Disk Controller; Intel 82072A; Intel 82072; NEC µPD765; NEC uPD765; Floppy controllers; 3 mode; 3-mode; 3mode; Floppy disk controller; NEC D765; NEC 765; NEC 765A; NEC D765A; NEC µPD765A; ΜPD765; ΜPD765A; NEC uPD765A; UPD765; UPD765A; D765A; Intel 8072A; NEC μPD765; NEC μPD765A; Floppy controller; FDC controller; Philips interface bus; Floppy diskette controller; Diskette controller; Floppy disk drive controller; 2HC

общая лексика

контроллер НГМД

Kelvin temperature         
  • '''Figure 2.5''' This simulation illustrates an argon atom as it would appear through a 400-power optical microscope featuring a reticle graduated with 50-micron (0.05&nbsp;mm) tick marks. This atom is moving with a velocity of 14.43 microns per second, which gives the atom a kinetic temperature of one-trillionth of a kelvin. The atom requires 13.9 seconds to travel 200 microns (0.2&nbsp;mm). Though the atom is being invisibly jostled due to zero-point energy, its translational motion seen here comprises all its kinetic energy.
  • '''Figure 7''' Water's temperature does not change during phase transitions as heat flows into or out of it. The total heat capacity of a mole of water in its liquid phase (the green line) is 7.5507&nbsp;kJ.
  • [[Joseph Louis Gay-Lussac]]
  • [[Guillaume Amontons]]
  • [[Johann Heinrich Lambert]]
  • [[Jacques Alexandre César Charles]]
  • [[Macquorn Rankine]]
ABSOLUTE MEASURE OF TEMPERATURE
Absolute temperature; Absolute Temperature; Thermodynamic temperature scale; Kelvin temperature; Temperature (thermodynamic); Atoms can have zero kinetic velocity and simultaneously be vibrating due to zero-point energy

общая лексика

температура Кельвина

Определение

disk controller
<hardware, storage> (Or "hard disk controller", HDC) The circuit which allows the CPU to communicate with a {hard disk}, floppy disk or other kind of disk drive. The most common disk controllers in use are IDE and SCSI controllers. Most home personal computers use IDE controllers. High end PCs, workstations and network {file servers} mostly have SCSI adaptors. (1998-03-16)
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Википедия

Effective temperature

The effective temperature of a body such as a star or planet is the temperature of a black body that would emit the same total amount of electromagnetic radiation. Effective temperature is often used as an estimate of a body's surface temperature when the body's emissivity curve (as a function of wavelength) is not known.

When the star's or planet's net emissivity in the relevant wavelength band is less than unity (less than that of a black body), the actual temperature of the body will be higher than the effective temperature. The net emissivity may be low due to surface or atmospheric properties, including greenhouse effect.

https://en.wikipedia.org/wiki/Effective temperature
Как переводится temperature controller на Русский язык
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