Patent Application
20210049383
The present invention is generally related to parking space vacancy determination, and more particularly related to a system and associated method for determining parking space vacancy using solar irradiance. In the herein disclosed system, frequent irradiance readings are carried out by one or more parking space sensors and compared to baseline irradiance readings and covered control irradiance readings carried out at a central hub.
All readings received at the hub can be communicated to a server at which a vacancy determination is made based upon an analysis of the parking space sensor data compared to the hub data. When the solar irradiance readings at the parking space sufficiently approach the covered control irradiance reading—and thus sufficiently differ from the baseline solar irradiance reading at the hub—a determination can be made that the parking space is occupied by a vehicle and is therefore not vacant.
Each of the parking space sensors includes a protective case to protect a solar cell and a temperature probe positioned within the parking space sensor; a solar irradiance present value reading may be calculated by utilizing both a solar cell reading and a temperature probe reading. Each of the parking space sensors is communicatively coupled to a central hub. The central hub includes a communication device plus a first solar cell for reading a local solar irradiance baseline value and a second covered solar cell for measuring a covered (or fully shaded) solar irradiance control value.
An exemplary embodiment of the herein disclosed system for determining parking space vacancy comprises a plurality of parking space sensors positioned on a street level of a parking space and communicatively coupled to a hub, wherein each parking space sensor is mounted to the street level of the parking space and includes a solar cell for measuring a solar irradiance present value and a temperature probe for measuring a present temperature; the hub includes a first hub solar cell for measuring a local solar irradiance baseline value, a second covered hub solar cell for measuring a covered solar irradiance control value, and a communication device communicatively coupled to a server and to the plurality of parking space sensors for receiving the solar irradiance present value and the present temperature from the plurality of parking space sensors; the server receives the solar irradiance present value, the present temperature, the local solar irradiance baseline value, and the covered solar irradiance control value, and determining whether the parking space is vacant.
In a preferred embodiment, the system is capable of largely powering itself by connecting the solar cell to a storage battery in each parking space sensor, thereby allowing the storage batter to store and utilize power generated by the solar cell. In certain embodiments, the hub may also be powered through solar power received by the uncovered hub solar cell.
An exemplary embodiment of the herein disclosed method for determining parking space vacancy comprises the steps of receiving one or more solar irradiance present values from one or more parking space sensors positioned on a street level of a parking space; receiving one or more present temperatures from the one or more parking space sensors; receiving a local solar irradiance baseline value from a hub; receiving a covered solar irradiance control value from the hub; and determining whether the parking space is vacant based upon the one or more solar irradiance present values, the one or more present temperatures, the local solar irradiance baseline value, and the covered solar irradiance control value.
Not applicable.
The field of determining parking space availability for vehicles is in constant development. Currently available solutions involve video cameras to visually inspect parking spaces for vacancy and moving or static sensors that detect electromagnetic fields to determine vehicle occupancy. But it is heretofore unknown to utilize solar irradiance measurements to track parking space availability.
A parking space sensor that utilizes solar irradiance to determine vacancy is advantageous. There is no wear and tear caused by components moving along a track and there is no need for complex video analysis algorithms to determine vacancy from video. Instead, simple and relatively inexpensive solar cell components can be utilized to create a network of solar irradiance measurement sensors in communication with a separate central hub taking local control solar irradiance measurements. Data from the parking spaces and the central hub can be compared and a simple determination of whether a vehicle is parked above a parking space sensor can be made quickly and accurately using a solar irradiance system that is low maintenance and easy to install.
A system and an associated method for determining parking space vacancy using solar irradiance is herein disclosed. Whether a parking space is occupied by a vehicle or is currently vacant can be determined by taking frequent irradiance readings at one or more parking space sensors and comparing the irradiance readings to baseline irradiance readings and covered control irradiance readings taken at a separate central hub. When the solar irradiance readings at the parking space sufficiently approach the covered control irradiance reading—and thus sufficiently differ from the baseline solar irradiance reading at the hub—a determination can be made that the parking space is occupied by a vehicle and is therefore not vacant.
An exemplary embodiment of the herein disclosed system for determining parking space vacancy comprises a plurality of parking space sensors positioned on a street level of a parking space and communicatively coupled to a hub, wherein each parking space sensor is mounted to the street level of the parking space and includes a solar cell for measuring a solar irradiance present value and a temperature probe for measuring a present temperature; the hub includes a first hub solar cell for measuring a local solar irradiance baseline value, a second covered hub solar cell for measuring a covered solar irradiance control value, and a communication device communicatively coupled to a server and to the plurality of parking space sensors for receiving the solar irradiance present value and the present temperature from the plurality of parking space sensors; the server receives the solar irradiance present value, the present temperature, the local solar irradiance baseline value, and the covered solar irradiance control value, and determining whether the parking space is vacant.
Referring to
One or more parking space sensors 110 are distributed throughout the street level of one or more parking spaces. Each of the one or more parking space sensors 110 takes or carried out readings or measurements of solar irradiance and transfers the solar irradiance data to separate central hub 120. Hub 120 is positioned outside the parking spaces and may be connected wirelessly, or by a hardline connection, to each of the one or more parking space sensors 110. Such a wireless data connection may be a Bluetooth™ connection, a WiFi connection, or any other wireless data connection capable to transferring solar irradiance and/or temperature data from one or more parking space sensors 110 to central hub 120.
Hub 120 carries out its own solar irradiance measurements (a local solar irradiance baseline value and a covered solar irradiance control value) and transmits these measurements plus the measurements received from one or more parking space sensors 110 to server 130. Server 130 may be any server capable of receiving solar irradiance data, processing the solar irradiance data to make the determination as to whether the parking space is vacant, and transmitting or disseminating the vacancy determination to one or more users. A user is a person or entity interested in knowing whether the parking space, or the parking spaces, are vacant and thus available for use or occupied by a vehicle and therefore unavailable for use. For example, server 130 may disseminate the determination through a mobile application that is downloadable to the user's mobile device and displays vacancy information to the user in a graphical format. In another example, server 130 may disseminate the vacancy determination by displaying the vacancy determination on a display screen that is visible to parking lot attendant or a security guard.
Referring to
Referring to
Central hub 120 includes power supply 370, communication device 360 for communicating wirelessly with server 130, first hub solar cell 321 for measuring a local solar irradiance baseline value, and second covered hub solar cell 322 for measuring a covered solar irradiance control value. Power supply 370 may be any power supply capable of powering the components of hub 120; in a preferred embodiment, power supply 370 is connected to first hub solar cell 321 and is a storage battery capable of storing solar energy collected by first hub solar cell 321. Communication device 360 may be any type of communication device capable of wirelessly communicating with server 130; for example, communication device 360 may be capable of Bluetooth™ data transmission, WiFi data transmission, or radio data transmission. In certain embodiments, communication device 360 may also be in wireless communication with one or more parking space sensors 110. First hub solar cell 321 is a solar cell that is exposed to the ambient light directly above hub 120. Second covered hub solar cell 322 is a solar cell that is fully covered to measure a covered solar irradiance control value; for example, second covered hub solar cell 322 may be covered by a screen or other opaque structure formed by the case of hub 120.
Referring to
As is apparent from the discussion regarding
An issue that may arise with the herein disclosed system and method is that a moving shadow or shade created by nearby objects or buildings can create a situation that may trigger a false occupied determination for the parking space. For example, as the day progresses a shadow cast by a nearby six-story building may progress across a parking lot and eventually plunge a vacant parking space completely into shadows, thus risking a false occupied determination for the parking space. To avoid or minimize this issue, the steps recited herein may be carried out at a high frequency (every 0.5 second, for example) and an occupied determination can be deferred until a sharp and/or immediate solar irradiance downturn is seen on the majority of parking space sensors 110. In other words, a slow decline in solar irradiance readings is to be marked as “vacant” as this situation is likely to be a shadow progressing across the parking space sensor 110, as opposed to a sudden solar irradiance shock that is more likely to be caused by a vehicle parking over the parking space sensor 110.
Throughout this specification reference has been made to each parking space sensor 110 having temperature probe 330 for measuring a temperature (referred to as a present temperature, see Step 420 in
Furthermore, throughout this specification reference has been made to the step of using the collected solar irradiance data to determine whether the parking space is vacant (Step 450 of the method shown in
While the present invention has been illustrated and described herein in terms of a preferred embodiment and several alternatives, it is to be understood that the devices, systems, and methods described herein can have a multitude of additional uses and applications. Accordingly, the invention should not be limited to just the particular description and various drawing figures contained in this specification that merely illustrate a preferred embodiment and application of the principles of the invention.
