Reflector 1.2.3
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BGP Optimal Route Reflection (ORR) is a feature that allows hot-potato routing in a iBGP network when route reflectors are present, without the need for newer operating system software on the border routers. The prerequisite is that the IGP is a link-state routing protocol.
1 Study Coverage 1.1 Reflector Antennas Product Introduction 1.2 Market by Type 1.2.1 Global Reflector Antennas Market Size by Type, 2017 VS 2021 VS 2028 1.2.2 Parabolic Reflector Antenna 1.2.3 Cylindrical Reflector Antenna 1.2.4 Corner Reflector Antenna 1.2.5 Spherical Reflector Antenna 1.3 Market by Application 1.3.1 Global Reflector Antennas Market Size by Application, 2017 VS 2021 VS 2028 1.3.2 Aviation 1.3.3 Military 1.3.4 Commercial 1.4 Study Objectives 1.5 Years Considered2 Global Reflector Antennas Production 2.1 Global Reflector Antennas Production Capacity (2017-2028) 2.2 Global Reflector Antennas Production by Region: 2017 VS 2021 VS 2028 2.3 Global Reflector Antennas Production by Region 2.3.1 Global Reflector Antennas Historic Production by Region (2017-2022) 2.3.2 Global Reflector Antennas Forecasted Production by Region (2023-2028) 2.4 North America 2.5 Europe 2.6 China 2.7 Japan 2.8 South Korea3 Global Reflector Antennas Sales in Volume and Value Estimates and Forecasts 3.1 Global Reflector Antennas Sales Estimates and Forecasts 2017-2028 3.2 Global Reflector Antennas Revenue Estimates and Forecasts 2017-2028 3.3 Global Reflector Antennas Revenue by Region: 2017 VS 2021 VS 2028 3.4 Global Reflector Antennas Sales by Region 3.4.1 Global Reflector Antennas Sales by Region (2017-2022) 3.4.2 Global Sales Reflector Antennas by Region (2023-2028) 3.5 Global Reflector Antennas Revenue by Region 3.5.1 Global Reflector Antennas Revenue by Region (2017-2022) 3.5.2 Global Reflector Antennas Revenue by Region (2023-2028) 3.6 North America 3.7 Europe 3.8 Asia-Pacific 3.9 Latin America 3.10 Middle East and Africa4 Competition by Manufactures 4.1 Global Reflector Antennas Production Capacity by Manufacturers 4.2 Global Reflector Antennas Sales by Manufacturers 4.2.1 Global Reflector Antennas Sales by Manufacturers (2017-2022) 4.2.2 Global Reflector Antennas Sales Market Share by Manufacturers (2017-2022) 4.2.3 Global Top 10 and Top 5 Largest Manufacturers of Reflector Antennas in 2021 4.3 Global Reflector Antennas Revenue by Manufacturers 4.3.1 Global Reflector Antennas Revenue by Manufacturers (2017-2022) 4.3.2 Global Reflector Antennas Revenue Market Share by Manufacturers (2017-2022) 4.3.3 Global Top 10 and Top 5 Companies by Reflector Antennas Revenue in 2021 4.4 Global Reflector Antennas Sales Price by Manufacturers 4.5 Analysis of Competitive Landscape 4.5.1 Manufacturers Market Concentration Ratio (CR5 and HHI) 4.5.2 Global Reflector Antennas Market Share by Company Type (Tier 1, Tier 2, and Tier 3) 4.5.3 Global Reflector Antennas Manufacturers Geographical Distribution 4.6 Mergers and Acquisitions, Expansion Plans5 Market Size by Type 5.1 Global Reflector Antennas Sales by Type 5.1.1 Global Reflector Antennas Historical Sales by Type (2017-2022) 5.1.2 Global Reflector Antennas Forecasted Sales by Type (2023-2028) 5.1.3 Global Reflector Antennas Sales Market Share by Type (2017-2028) 5.2 Global Reflector Antennas Revenue by Type 5.2.1 Global Reflector Antennas Historical Revenue by Type (2017-2022) 5.2.2 Global Reflector Antennas Forecasted Revenue by Type (2023-2028) 5.2.3 Global Reflector Antennas Revenue Market Share by Type (2017-2028) 5.3 Global Reflector Antennas Price by Type 5.3.1 Global Reflector Antennas Price by Type (2017-2022) 5.3.2 Global Reflector Antennas Price Forecast by Type (2023-2028)6 Market Size by Application 6.1 Global Reflector Antennas Sales by Application 6.1.1 Global Reflector Antennas Historical Sales by Application (2017-2022) 6.1.2 Global Reflector Antennas Forecasted Sales by Application (2023-2028) 6.1.3 Global Reflector Antennas Sales Market Share by Application (2017-2028) 6.2 Global Reflector Antennas Revenue by Application 6.2.1 Global Reflector Antennas Historical Revenue by Application (2017-2022) 6.2.2 Global Reflector Antennas Forecasted Revenue by Application (2023-2028) 6.2.3 Global Reflector Antennas Revenue Market Share by Application (2017-2028) 6.3 Global Reflector Antennas Price by Application 6.3.1 Global Reflector Antennas Price by Application (2017-2022) 6.3.2 Global Reflector Antennas Price Forecast by Application (2023-2028)7 North America 7.1 North America Reflector Antennas Market Size by Type 7.1.1 North America Reflector Antennas Sales by Type (2017-2028) 7.1.2 North America Reflector Antennas Revenue by Type (2017-2028) 7.2 North America Reflector Antennas Market Size by Application 7.2.1 North America Reflector Antennas Sales by Application (2017-2028) 7.2.2 North America Reflector Antennas Revenue by Application (2017-2028) 7.3 North America Reflector Antennas Sales by Country 7.3.1 North America Reflector Antennas Sales by Country (2017-2028) 7.3.2 North America Reflector Antennas Revenue by Country (2017-2028) 7.3.3 U.S. 7.3.4 Canada
After September 30, 2022 and prior to February 27, 2023 any representations with respect to energy use or efficiency of general service fluorescent lamps, incandescent reflector lamps, and general service incandescent lamps must be in accordance with the results of testing pursuant to this appendix or the test procedures as they appeared in appendix R to subpart B of part 430 revised as of January 1, 2021. On or after February 27, 2023, any representations, including certifications of compliance for lamps subject to any energy conservation standard, made with respect to the energy use or efficiency of general service fluorescent lamps, incandescent reflector lamps, and general service incandescent lamps must be made in accordance with the results of testing pursuant to this appendix.
This appendix specifies the test methods required for determining the electrical and photometric performance characteristics of general service fluorescent lamps (GSFLs), incandescent reflector lamps (IRLs), and general service incandescent lamps (GSILs).
Beam contributor means an indivisible optical assembly including a lens, reflector, and light source, that is part of an integral beam headlighting system and contributes only a portion of a headlamp beam.
Effective light-emitting surface means that portion of a lamp that directs light to the photometric test pattern, and does not include transparent lenses, mounting hole bosses, reflex reflector area, beads or rims that may glow or produce small areas of increased intensity as a result of uncontrolled light from an area of 1/2 radius around a test point.
Integral beam headlamp means a headlamp (other than a standardized sealed beam headlamp designed to conform to paragraph S10.13 or a replaceable bulb headlamp designed to conform to paragraph S10.15) comprising an integral and indivisible optical assembly including lens, reflector, and light source, except that a headlamp conforming to paragraph S10.18.8 or paragraph S10.18.9 may have a lens designed to be replaceable.
Replaceable bulb headlamp means a headlamp comprising a bonded lens and reflector assembly and one or two replaceable light sources, except that a headlamp conforming to paragraph S10.18.8 or paragraph S10.18.9 may have a lens designed to be replaceable.
Add a light to an object in class cfgvehicles.Each reflector requires a selection in relevant model vis LODs (e.g. \"L svetlo\") for the flare effect. Requires two memory points in memory LOD - light spawn position and direction e.g. position \"L svetlo\" and direction \"konec L svetla\".
The memory point you assign to position parameter is where the light source itself will be.The one you put to direction is the way your light will shine.The cone itself is set using innerAngle, outerAngle and coneFadeCoef.innerAngle sets the cone in which the light has it is full intensity.outerAngle sets the cone outside of which the light has zero intensity.coneFadeCoef is a coefficient that describes attenuation of the light between innerAngle and outerAngle. 1 equals linear attenuation, higher or lower value changes it, meaning how sharp/blurred will the edge of the lightcone as a whole be.Note that both the angles represent full angle of the cone, not just \"angular offset\" from direction of the light. If you set it to 90 degrees, it means the cone is 45 degrees to the \"left\" and 45 to the \"right\" of the direction specified by your memory points.As a spot light, reflectors are not made for cones above 180 degrees.Some time ago BIS made changes to the lighting system to allow for higher light variety during night time. One of the effects it had on configs of lights was that you need to set higher intensity than before the change to get the same results.color[] and ambient[] seem to have changed from RGB from 0-1 to way higher values - see example.
This type of solar collector mainly includes the single-axis tracking collectors and two-axes tracking collectors. Single-axis tracking collectors include linear parabolic trough collectors (PTCs), linear Fresnel reflectors (LFRs), and cylindrical trough collector (CTCs). They have a two-dimensional concentrating effect. Two-axes tracking collectors include the parabolic dish collector and solar tower (heliostat field) collector. They have a three-dimensional concentrating effect. The tracking collectors usually work as medium- and high-temperature collectors. Water, oil, or molten salt can be used as working fluid. 153554b96e