Indoor/sensors/radio/model/WiFiModelLogDistCeiling.h

#ifndef WIFIMODELLOGDISTCEILING_H
#define WIFIMODELLOGDISTCEILING_H

#include "../../../floorplan/v2/Floorplan.h"
#include "../../../floorplan/v2/FloorplanCeilings.h"

#include "../../../Assertions.h"
#include "WiFiModel.h"
#include "LogDistanceModel.h"
#include "../VAPGrouper.h"
#include "../../../misc/Debug.h"

/**
 * signal-strength estimation using log-distance model
 * including ceilings between AP and position
 */
class WiFiModelLogDistCeiling : public WiFiModel {

public:

	/** parameters describing one AP to the model */
	struct APEntry {

		Point3 position_m;	// the AP's position (in meter)
		float txp;			// sending power (-40)
		float exp;			// path-loss-exponent (~2.0 - 4.0)
		float waf;			// attenuation per ceiling/floor (~-8.0)

		/** ctor */
		APEntry(const Point3 position_m, const float txp, const float exp, const float waf) :
			position_m(position_m), txp(txp), exp(exp), waf(waf) {;}

	};

private:

	/** map of all APs (and their parameters) known to the model */
	std::unordered_map<MACAddress, APEntry> accessPoints;

//	/** position (height) of all ceilings (in meter) */
//	std::vector<float> ceilingsAtHeight_m;
	Floorplan::Ceilings ceilings;

public:

	/** ctor with floorplan (needed for ceiling position) */
	WiFiModelLogDistCeiling(const Floorplan::IndoorMap* map) : ceilings(map) {

		// sanity checks
		Assert::isTrue(map->floors.size() >= 1, "map has no floors?!");


	}

	/** get a list of all APs known to the model */
	std::vector<AccessPoint> getAllAPs() const {
		std::vector<AccessPoint> aps;
		for (const auto it : accessPoints) {aps.push_back(AccessPoint(it.first));}
		return aps;
	}

	/** load AP information from the floorplan. use the given fixed TXP/EXP/WAF for all APs */
	void loadAPs(const Floorplan::IndoorMap* map, const float txp = -40.0f, const float exp = 2.5f, const float waf = -8.0f) {

		for (const Floorplan::Floor* floor : map->floors) {
			for (const Floorplan::AccessPoint* ap : floor->accesspoints) {
				const APEntry ape(ap->getPos(floor), txp, exp, waf);
				addAP(MACAddress(ap->mac), ape);
			}
		}

	}

	/** load AP information from the floorplan. use the given fixed TXP/EXP/WAF for all APs */
	void loadAPs(const Floorplan::IndoorMap* map, const VAPGrouper& vg, const float txp = -40.0f, const float exp = 2.5f, const float waf = -8.0f) {

		for (const Floorplan::Floor* floor : map->floors) {
			for (const Floorplan::AccessPoint* ap : floor->accesspoints) {
				const APEntry ape(ap->getPos(floor), txp, exp, waf);
				const MACAddress mac = vg.getBaseMAC(MACAddress(ap->mac));
				Log::add("WiModLDC", "AP: " + ap->mac + " -> " + mac.asString());
				addAP(MACAddress(mac), ape);
			}
		}

	}

	/** make the given AP (and its parameters) known to the model */
	void addAP(const MACAddress& accessPoint, const APEntry& params) {

		// sanity check
		Assert::isBetween(params.waf, -99.0f, 0.0f, "WAF out of bounds [-99:0]");
		Assert::isBetween(params.txp, -50.0f, -30.0f, "TXP out of bounds [-50:-30]");
		Assert::isBetween(params.exp, 1.0f, 4.0f, "EXP out of bounds [1:4]");

		Assert::equal(accessPoints.find(accessPoint), accessPoints.end(), "AccessPoint already present! VAP-Grouping issue?");

		// add
		accessPoints.insert( std::pair<MACAddress, APEntry>(accessPoint, params) );

	}

	/** remove all added APs */
	void clear() {
		accessPoints.clear();
	}

	float getRSSI(const MACAddress& accessPoint, const Point3 position_m) const override {

		// try to get the corresponding parameters
		const auto it = accessPoints.find(accessPoint);

		// AP unknown? -> NAN
		if (it == accessPoints.end()) {return NAN;}

		// the access-points' parameters
		const APEntry& params = it->second;

		// free-space (line-of-sight) RSSI
		const float distance_m = position_m.getDistance(params.position_m);
		const float rssiLOS = LogDistanceModel::distanceToRssi(params.txp, params.exp, distance_m);

		// WAF loss (params.waf is a negative value!) -> WAF loss is also a negative value
		const float wafLoss = params.waf * ceilings.numCeilingsBetween(position_m, params.position_m);

		// combine
		return rssiLOS + wafLoss;

	}

};


#endif // WIFIMODELLOGDISTCEILING_H