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<?php
/*
* Copyright 2014 Google Inc.
*
* Licensed under the Apache License, Version 2.0 (the "License"); you may not
* use this file except in compliance with the License. You may obtain a copy of
* the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
* License for the specific language governing permissions and limitations under
* the License.
*/
namespace Google\Service\Solar;
class DataLayers extends \Google\Collection
{
/**
* No quality is known.
*/
public const IMAGERY_QUALITY_IMAGERY_QUALITY_UNSPECIFIED = 'IMAGERY_QUALITY_UNSPECIFIED';
/**
* Solar data is derived from aerial imagery captured at low-altitude and
* processed at 0.1 m/pixel.
*/
public const IMAGERY_QUALITY_HIGH = 'HIGH';
/**
* Solar data is derived from enhanced aerial imagery captured at high-
* altitude and processed at 0.25 m/pixel.
*/
public const IMAGERY_QUALITY_MEDIUM = 'MEDIUM';
/**
* Solar data is derived from enhanced satellite imagery processed at 0.25
* m/pixel.
*/
public const IMAGERY_QUALITY_LOW = 'LOW';
/**
* Solar data is derived from enhanced satellite imagery processed at 0.25
* m/pixel.
*/
public const IMAGERY_QUALITY_BASE = 'BASE';
protected $collection_key = 'hourlyShadeUrls';
/**
* The URL for the annual flux map (annual sunlight on roofs) of the region.
* Values are kWh/kW/year. This is *unmasked flux*: flux is computed for every
* location, not just building rooftops. Invalid locations are stored as
* -9999: locations outside our coverage area will be invalid, and a few
* locations inside the coverage area, where we were unable to calculate flux,
* will also be invalid.
*
* @var string
*/
public $annualFluxUrl;
/**
* The URL for an image of the DSM (Digital Surface Model) of the region.
* Values are in meters above EGM96 geoid (i.e., sea level). Invalid locations
* (where we don't have data) are stored as -9999.
*
* @var string
*/
public $dsmUrl;
/**
* Twelve URLs for hourly shade, corresponding to January...December, in
* order. Each GeoTIFF will contain 24 bands, corresponding to the 24 hours of
* the day. Each pixel is a 32 bit integer, corresponding to the (up to) 31
* days of that month; a 1 bit means that the corresponding location is able
* to see the sun at that day, of that hour, of that month. Invalid locations
* are stored as -9999 (since this is negative, it has bit 31 set, and no
* valid value could have bit 31 set as that would correspond to the 32nd day
* of the month). An example may be useful. If you want to know whether a
* point (at pixel location (x, y)) saw sun at 4pm on the 22nd of June you
* would: 1. fetch the sixth URL in this list (corresponding to June). 1. look
* up the 17th channel (corresponding to 4pm). 1. read the 32-bit value at (x,
* y). 1. read bit 21 of the value (corresponding to the 22nd of the month).
* 1. if that bit is a 1, then that spot saw the sun at 4pm 22 June. More
* formally: Given `month` (1-12), `day` (1...month max; February has 28 days)
* and `hour` (0-23), the shade/sun for that month/day/hour at a position `(x,
* y)` is the bit ``` (hourly_shade[month - 1])(x, y)[hour] & (1 << (day - 1))
* ``` where `(x, y)` is spatial indexing, `[month - 1]` refers to fetching
* the `month - 1`st URL (indexing from zero), `[hour]` is indexing into the
* channels, and a final non-zero result means "sunny". There are no leap
* days, and DST doesn't exist (all days are 24 hours long; noon is always
* "standard time" noon).
*
* @var string[]
*/
public $hourlyShadeUrls;
protected $imageryDateType = Date::class;
protected $imageryDateDataType = '';
protected $imageryProcessedDateType = Date::class;
protected $imageryProcessedDateDataType = '';
/**
* The quality of the result's imagery.
*
* @var string
*/
public $imageryQuality;
/**
* The URL for the building mask image: one bit per pixel saying whether that
* pixel is considered to be part of a rooftop or not.
*
* @var string
*/
public $maskUrl;
/**
* The URL for the monthly flux map (sunlight on roofs, broken down by month)
* of the region. Values are kWh/kW/year. The GeoTIFF pointed to by this URL
* will contain twelve bands, corresponding to January...December, in order.
*
* @var string
*/
public $monthlyFluxUrl;
/**
* The URL for an image of RGB data (aerial photo) of the region.
*
* @var string
*/
public $rgbUrl;
/**
* The URL for the annual flux map (annual sunlight on roofs) of the region.
* Values are kWh/kW/year. This is *unmasked flux*: flux is computed for every
* location, not just building rooftops. Invalid locations are stored as
* -9999: locations outside our coverage area will be invalid, and a few
* locations inside the coverage area, where we were unable to calculate flux,
* will also be invalid.
*
* @param string $annualFluxUrl
*/
public function setAnnualFluxUrl($annualFluxUrl)
{
$this->annualFluxUrl = $annualFluxUrl;
}
/**
* @return string
*/
public function getAnnualFluxUrl()
{
return $this->annualFluxUrl;
}
/**
* The URL for an image of the DSM (Digital Surface Model) of the region.
* Values are in meters above EGM96 geoid (i.e., sea level). Invalid locations
* (where we don't have data) are stored as -9999.
*
* @param string $dsmUrl
*/
public function setDsmUrl($dsmUrl)
{
$this->dsmUrl = $dsmUrl;
}
/**
* @return string
*/
public function getDsmUrl()
{
return $this->dsmUrl;
}
/**
* Twelve URLs for hourly shade, corresponding to January...December, in
* order. Each GeoTIFF will contain 24 bands, corresponding to the 24 hours of
* the day. Each pixel is a 32 bit integer, corresponding to the (up to) 31
* days of that month; a 1 bit means that the corresponding location is able
* to see the sun at that day, of that hour, of that month. Invalid locations
* are stored as -9999 (since this is negative, it has bit 31 set, and no
* valid value could have bit 31 set as that would correspond to the 32nd day
* of the month). An example may be useful. If you want to know whether a
* point (at pixel location (x, y)) saw sun at 4pm on the 22nd of June you
* would: 1. fetch the sixth URL in this list (corresponding to June). 1. look
* up the 17th channel (corresponding to 4pm). 1. read the 32-bit value at (x,
* y). 1. read bit 21 of the value (corresponding to the 22nd of the month).
* 1. if that bit is a 1, then that spot saw the sun at 4pm 22 June. More
* formally: Given `month` (1-12), `day` (1...month max; February has 28 days)
* and `hour` (0-23), the shade/sun for that month/day/hour at a position `(x,
* y)` is the bit ``` (hourly_shade[month - 1])(x, y)[hour] & (1 << (day - 1))
* ``` where `(x, y)` is spatial indexing, `[month - 1]` refers to fetching
* the `month - 1`st URL (indexing from zero), `[hour]` is indexing into the
* channels, and a final non-zero result means "sunny". There are no leap
* days, and DST doesn't exist (all days are 24 hours long; noon is always
* "standard time" noon).
*
* @param string[] $hourlyShadeUrls
*/
public function setHourlyShadeUrls($hourlyShadeUrls)
{
$this->hourlyShadeUrls = $hourlyShadeUrls;
}
/**
* @return string[]
*/
public function getHourlyShadeUrls()
{
return $this->hourlyShadeUrls;
}
/**
* When the source imagery (from which all the other data are derived) in this
* region was taken. It is necessarily somewhat approximate, as the images may
* have been taken over more than one day.
*
* @param Date $imageryDate
*/
public function setImageryDate(Date $imageryDate)
{
$this->imageryDate = $imageryDate;
}
/**
* @return Date
*/
public function getImageryDate()
{
return $this->imageryDate;
}
/**
* When processing was completed on this imagery.
*
* @param Date $imageryProcessedDate
*/
public function setImageryProcessedDate(Date $imageryProcessedDate)
{
$this->imageryProcessedDate = $imageryProcessedDate;
}
/**
* @return Date
*/
public function getImageryProcessedDate()
{
return $this->imageryProcessedDate;
}
/**
* The quality of the result's imagery.
*
* Accepted values: IMAGERY_QUALITY_UNSPECIFIED, HIGH, MEDIUM, LOW, BASE
*
* @param self::IMAGERY_QUALITY_* $imageryQuality
*/
public function setImageryQuality($imageryQuality)
{
$this->imageryQuality = $imageryQuality;
}
/**
* @return self::IMAGERY_QUALITY_*
*/
public function getImageryQuality()
{
return $this->imageryQuality;
}
/**
* The URL for the building mask image: one bit per pixel saying whether that
* pixel is considered to be part of a rooftop or not.
*
* @param string $maskUrl
*/
public function setMaskUrl($maskUrl)
{
$this->maskUrl = $maskUrl;
}
/**
* @return string
*/
public function getMaskUrl()
{
return $this->maskUrl;
}
/**
* The URL for the monthly flux map (sunlight on roofs, broken down by month)
* of the region. Values are kWh/kW/year. The GeoTIFF pointed to by this URL
* will contain twelve bands, corresponding to January...December, in order.
*
* @param string $monthlyFluxUrl
*/
public function setMonthlyFluxUrl($monthlyFluxUrl)
{
$this->monthlyFluxUrl = $monthlyFluxUrl;
}
/**
* @return string
*/
public function getMonthlyFluxUrl()
{
return $this->monthlyFluxUrl;
}
/**
* The URL for an image of RGB data (aerial photo) of the region.
*
* @param string $rgbUrl
*/
public function setRgbUrl($rgbUrl)
{
$this->rgbUrl = $rgbUrl;
}
/**
* @return string
*/
public function getRgbUrl()
{
return $this->rgbUrl;
}
}
// Adding a class alias for backwards compatibility with the previous class name.
class_alias(DataLayers::class, 'Google_Service_Solar_DataLayers');