The viewing of selectable products from within a refrigerated glass front vending machine typically include two spaced apart transparent glass panes for providing thermal insulation. The customer selects from among the designated viewable products by depressing designated selection buttons located off to one side of the viewing area, and having entered sufficient credit for the selection receives the vended product.
A customer enters the identification associated with one of the many viewable products within a glass front vendor and makes a two digit entry on a keypad or selection buttons located away from the viewed products. Many different selection methods are used to select products from a vending machine, ranging from depressing alpha-numeric marked buttons that activate sensors, to the touching of identified areas on a screen or panel.
Many known technologies for identifying areas of touch on a screen could be utilized such as Acoustic Pulse Recognition (APR) which comprises a glass display overlay or other rigid substrate, with four piezoelectric transducers mounted on the back surface. The transducers are mounted on two diagonally opposite corners out of the visible area and connected via a flex cable to a controller card. The impact when the screen is touched, or the friction caused while dragging between a user's finger or stylus and the glass, creates an acoustic wave. The wave radiates away from the touch point, making its way to the transducers which produce electrical signals proportional to the acoustic waves. These signals are amplified in the controller card and then converted into a digital stream of data. The touch location is determined by comparing the data to a profile. The APR is designed reject ambient and extraneous sounds, as these do not match a stored sound profile. The key is that a touch at each position on the glass generates a unique sound. Four tiny transducers attached to the edges of the touch-screen glass pick up the sound of the touch. The sound is then digitized by the controller and compared to a list of prerecorded sounds for every position on the glass. The cursor position is instantly updated to the touch location. By using the sound generated when a finger or stylus touches the glass, APR allows users to touch the screen with practically anything, such as a fingernail, gloved hand, pen or corner of credit card.
Dispersive Signal Technology (DST) represents a fundamentally different approach to touch. Unlike other solutions that recognize touch by the interruption of electrical fields, acoustic waves, optical fields, or infrared light, Dispersive Signal Technology recognizes touch by interpreting bending waves created in the overlay substrate via the impact of a touch. DST locates sensors in each corner of the touch screen, which measure the vibration energy. Advanced dispersion adjustment algorithms are then applied to the data, allowing accurate reporting of each touch. This approach helps eliminate issues with screen contaminants and surface scratches, and also allows a touch to be registered while a palm and/or object is resting on the screen's surface. A finger, gloved hand or stylus can initiate a touch while a person's palm and drink are on the surface. The touch creates a vibration, which radiates a bending wave through the substrate from the point of contact spreading out to the edges, and the resting items are ignored as they do not generate any vibration energy.
An established technology using waves to detect contact is Surface Acoustic Wave (SAW), which generates high frequency waves on the surface of a glass screen, and their attenuation by the contact of a finger, is used to detect the touch location. This technique is “time-of-flight”, where the time for the disturbance to reach one or more sensors is used to detect the location. Such an approach is possible when the medium behaves in a non=dispersive manner i.e. the velocity of the waves does not vary significantly over the frequency range of interest. A contact sensitive device comprising a member capable of supporting bending waves, having a plurality (e.g. three or more) sensors mounted on the member for measuring bending wave vibration in the member, whereby each sensor determines a measured bending wave signal. A processor calculates a location of a contact on the member from the measured bending wave signals, in that the processor calculates a phase angle for each measured bending wave signal, and then calculates a phase difference between the phase angles of least two pairs of sensors from which the location of the contact is determined. Ultrasonic acoustic wave contact detecting apparatuses are in widespread use. Examples of their applications include operating screens of personal computers, ticket dispensers at train stations, copiers installed in convenience stores and ATM's at financial institutions. These acoustic wave contact detecting apparatus utilize transducers, including piezoelectric vibrators provided on a substrate (touch panel) formed of glass or the like. These transducers function both as generating means for bulk waves and as sensors for detecting acoustic waves which are scattered by a finger or the like that contacts the touch panel. The surface acoustic waves are scattered by a finger or the like. The scattering of the surface acoustic waves is detected by detection means. The detected signal is referenced against a clock signal of a controller, and the position at which the surface acoustic waves are scattered is determined.
Another method for locating the positions of fingers knocking on a pane of glass is Acoustic Tap Tracking (ATT). The finger tap excitation can change considerably from one hit to the next. Variations occur depending on how the glass is struck, the type of glass used, and how the glass is supported. Contact pickups made of polyvinylidene fluoride (PVDF) piezoelectric foil 52, are placed near the perimeter of a glass pane produce signals when the glass is hit. They are bonded with common adhesive to a glass window solidly supported by rubber anchors along its entire perimeter. To track taps more reliably, using a simple static threshold is generally not adequate. Amplitude dependence is one factor, because the leading edge for a knuckle-tap is not sufficiently abrupt. The characteristics of the first arrival can vary widely from transducer to transducer and impact to impact. A significant problem posed by the variable amount of low-amplitude, higher-frequency, dispersive deflection often arrives before the main wavefront. Likewise, sharp impacts (e.g., snapping a metal ring against the glass instead of one's knuckle) excite rapidly moving modes. A microcontroller continuously digitizes the analog signals, from four transducers into 10 bits at over 10 kHz enables a more detailed and robust embedded analysis to look at other waveform features (e.g., peak amplitudes and waveform shape) for each tap. The microcontroller continuously samples the signals from each transducer into a rotating buffer. Upon detecting a transducer signal above a noise threshold, a “knock” event is declared, and 10 millisecond (ms) worth of data are stored from all four inputs (including 3 ms of data before the trigger occurs). This buffer is then scanned for every significant peak in the absolute-value waveform produced by each transducer, and descriptive parameters (e.g., peak height, width, and mean arrival time relative to the initial trigger) are extracted for each peak including any small peaks arriving earlier. These parameters are sent, together with a count of the number of zero-crossings across the data acquisition interval (too many zero crossings indicate a sharp hit with different timing). A connected personal computer then processes the timing determined for each first peak by a second order polynomial that was obtained from a linear least-squares fit to a set of calibration to produce an estimate of the impact location in Cartesian coordinates. In addition to increasing the reliability of the results, the use of a microcontroller readily enables more channels of gestural input (e.g., measuring the strike intensity and classifying the type of strike). Also extracted is an estimate of accuracy or validity by crosschecking the detected waveform characteristics from the different sensors and examining the differences between the four position estimates obtained from the four different sensor triplets (since there are four pickups, there is one redundant degree of freedom). The sensor strips are very small and do not significantly block the window's view.
The present invention provides a simple method to utilize the typical double glass pane construction of a refrigerated glass front vending machine for making product selections on the glass front without modifying the glass panes or their support, and without requiring sensors on the outer glass pane. It does not require the generation of high frequency waves, nor does it utilize the high frequency sounds from the touching of the outer glass pane.
This invention provides an improved vending machine apparatus and method for selecting viewable products through its glass front pane by applying a light tap at the relative product designation on the glass front pane. The designations are positioned relative to the products and require only one light tap of the finger to make the product selection, and without having to look away from the viewable product. The method provides a simple and effective way to determine a product selection at a typical refrigerated glass front vending machine having two spaced apart glass panes without requiring any apparatus at the outer glass pane. No changes are required for the glass panes, their mounting, and insulation design. A single light tap by the customer at the product designation on the outside glass pane transfers the lateral movement rearward to the inner glass pane through the insulated space there between and causes three or more spaced apart and resiliently suspended inertia masses to develop their unique rate of movement which are sensed and provide outputs which are used to determine the product selected.
Thus according to one aspect of the invention there is provided a method of vending a viewable product within a refrigerated, double glass front vending machine comprising the steps of: (a) detecting a light tap by a customer on a selectable product reference area on the outer glass pane area by use of at least three or more spaced apart piezo discs with their resilient first portions attached to the inner glass pane and oriented in the same general plane therewith; (b) providing a suspended inertia mass attached to each of the piezo discs resilient second portions; (c) monitoring the resultant signals produced when the inner glass pane area is first moved rearward from its rest position and in respect to the suspended inertia mass movement and the resilient piezo disc attached first portions; (d) determining the arrival times of said signals; (e) comparing the arrival time intervals between the at least three sensors to the acceptable arrival time intervals stored in memory for each product reference area; (f) determining the selected product reference area; (g) determining the selected product and its value; (h) determining that the amount credited to the customer at least equals the selected product value; (i) vending the product selected; and (j) refunding any over credited amounts.
According to yet another aspect of the invention there is provided a method of vending a viewable product within a refrigerated, double glass front vending machine comprising the steps of: (a) detecting a light tap by a customer on a selectable product reference area on the outer glass pane area by use of three or more spaced apart resilient members with their first portions attached about the inner glass pane and with a suspended inertia mass at its unattached second portion; (b) sensing the relative movement between the suspended inertia mass and the resilient member attached first portions, using piezo, resistive, capacitive, inductive, or optical sensors; (c) monitoring the resultant sensor signal produced when its inner glass pane area is first moved rearward from its rest position and in respect to the movement of its suspended inertia mass; (d) determining the arrival times of the sensor signals; (e) comparing the arrival time intervals between at least three sensors to the acceptable arrival time intervals stored in memory for each product reference area; (f) determining the selected product reference area; (g) determining the selected product and its value; (h) determining that the amount credited to the customer at least equals the selected product value; (i) vending the product selected; and (j) refunding any over credited amounts.
According to yet another aspect of the invention there is provided a method of vending a viewable product within a refrigerated, double glass front vending machine comprising the steps of. (a) detecting a light tap by a customer on a selectable product reference area on the outer glass pane area by use of three or more spaced apart resilient members with first portions attached about the inner glass pane, each with a suspended inertia mass at its unattached second portion; (b) providing a suspended inertia mass and resilient member combination that resonates at a selected rate faster than the natural inner glass pane's lateral movement (c) sensing the relative movement between the suspended inertia mass and the resilient member attached first portion, using piezo, resistive, capacitive, inductive, or optical sensors; (d) monitoring the resultant sensor signal produced when its inner glass pane area is first moved rearward from its rest position and in respect to the movement of its suspended inertia mass; (e) determining the arrival times of said signals; (f) comparing the arrival time intervals between at least three sensors to the acceptable arrival time intervals stored in memory for each product reference area; (g) determining the selected product reference area; (h) determining the selected product and its value; (i) determining that the amount credited to the customer at least equals the selected product value; (j) vending the product selected; and (k) refunding any over credited amounts.
According to yet a further aspect of the invention there is provided a method of vending a viewable product within a refrigerated, double glass front vending machine comprising the steps of: (a) detecting a light tap by a customer on a selectable product reference area on the outer glass pane area by use of three or more spaced apart resilient members with first portions attached about the inner glass pane, each with a suspended inertia mass at its unattached second portion; (b) providing a suspended inertia mass and resilient member combination that resonates at a selected faster rate than the natural inner glass pane's lateral movement (c) sensing the relative movement between the suspended inertia mass and the resilient member attached first portion, using piezo, resistive, capacitive, inductive, or optical sensors; (d) monitoring the resultant sensor signal produced when the inner glass pane is first moved rearward from its rest position and in respect to the movement of its suspended inertia mass; (e) identifying the first alternation of each suspended inertia mass to determine the arrival times of said signals; (f) comparing the arrival time intervals between at least three sensors to the acceptable arrival time intervals stored in memory for each product reference area; and (g) communicating the selected product to a microprocessor.
According to yet a further aspect of the invention there is provided a method of vending a viewable product within a refrigerated, double glass front vending machine comprising the steps of (a) detecting a light tap by a customer on a selectable product reference area on the outer glass pane area by use of three or more spaced apart resilient members with first portions attached about the inner glass pane, each with a suspended inertia mass at its unattached second portion; (b) providing a suspended inertia mass and resilient member combination that resonates at a selected faster rate than the natural inner glass pane's lateral movement (c) sensing the relative movement between the suspended inertia mass and the resilient member attached first portion, using piezo, resistive, capacitive, or optical sensors; (d) monitoring the resultant sensor signal produced when the inner glass pane is first moved rearward from its rest position and in respect to the predetermined movement of its suspended inertia mass; (e) identifying a designated threshold level of the first alternation of each suspended inertia mass to determine the arrival times of said signals; (f) comparing the arrival time intervals between at least three sensors to the acceptable arrival time intervals stored in memory for each product reference area; and (g) communicating the selected product to a microprocessor.
According to yet a further aspect of the invention there is provided a method of vending a viewable product within a refrigerated, double glass front vending machine comprising the steps of: (a) detecting a light tap by a customer on a selectable product reference area on the outer glass pane area by use of at least three space located apart resilient members on the inner glass pane, having their first portions attached thereto, and each with a suspended inertia mass at its unattached second portion; (b) providing a suspended inertia mass and resilient member combination that favors the direction of the inner glass pane's natural lateral movement but designed to resonate at a faster rate (c) sensing the relative movement between the suspended inertia mass and the attached resilient member's first portion, using piezo, resistive, capacitive, or optical sensors; (d) monitoring the resultant sensor signal produced when the inner glass pane is first moved rearward from its rest position and in respect to the movement of its suspended inertia mass; (e) identifying a designated threshold level of the first alternation of each suspended inertia mass to determine the arrival times of said signals; (f) comparing the arrival time intervals between at least three sensors to the acceptable arrival time intervals stored in memory for each product reference area; and (g) communicating the selected product to a microprocessor.
According to yet a further aspect of the invention there is provided a method of indicating a viewable item within a glass front vending machine comprising the steps of. (a) detecting a light tap by a customer on a selectable product reference area on the glass pane area by use of at least three space located apart resilient members having their first portions attached thereto, and each with a suspended inertia mass at its unattached second portion; (b) providing a suspended inertia mass and resilient member combination that favors the glass pane's natural lateral movement but resonates at a faster rate (c) sensing the relative movement between the suspended inertia mass and the resilient member attached first portion, using piezo, resistive, capacitive, inductive, or optical sensors; (d) monitoring the resultant sensor signal produced when the glass pane is first moved rearward from its rest position and in respect to the movement of its suspended inertia mass; (e) identifying a designated threshold level of the first alternation of each suspended inertia mass to determine the arrival times of said signals; (f) comparing the arrival time intervals between at least three sensors to the acceptable arrival time intervals stored in memory for each product reference area; and (g) communicating the selected item.
According to yet a further aspect of the invention there is provided a method of indicating a viewable item within a glass front vending machine comprising the steps of. (a) detecting a light tap by a customer on a selectable product reference area on the glass pane area by use of three or more spaced apart resilient members having their first portions attached thereto, and each with a suspended inertia mass at its unattached second portion; (b) providing a suspended inertia mass and resilient member combination that favors the glass pane's natural lateral movement but resonates at a faster rate; (c) providing a suspended inertia mass and resilient member combination that is resilient enough to resist responding to the glass movements that are less than the expected light tap of a finger and to oscillate the suspended inertia mass when it equals or exceeds it; (d) sensing the relative movement between the suspended inertia mass and the resilient member attached first portion, using piezo, resistive, capacitive, inductive, or optical sensors; (e) monitoring the resultant sensor signal produced when the glass pane is first moved rearward from its rest position and in respect to the movement of its suspended inertia mass; (f) identifying a designated threshold level of the first alternation of each suspended inertia mass to determine the arrival times of said signals; (g) comparing the arrival time intervals between at least three sensors to the acceptable arrival time intervals stored in memory for each product reference area; and (h) communicating the selected item.
Referring to the figures there is generally illustrated therein a preferred embodiment of a glass front vending machine that incorporates the principles of this invention. While the preferred embodiment of this invention will be described with its applicability to a glass front vending machine for refrigerated products, it will be understood that the broad principles of the invention are not limited to such product selection application or to the specifics of the preferred embodiment disclosed. The described disclosure represents one clear example of a selection system incorporating the principles of the claimed invention, but the invention is not intended to be construed in a limiting manner as a result of the preferred embodiment disclosure.
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In the present invention the initial sounds produced within and around the outer glass pane by a tap are somewhat isolated from the spaced apart inner glass pane by the space between them. The two rectangular glass panes are sealed and suspended at their outer edge. The rate of natural lateral movement of the edge supported inner glass pane of a typical refrigerated glass front vending machine may occur in the vicinity of 60 to 100 times per second, whereas the frequency of the sounds produced by an initial impact within and about the surface of the outer glass pane can range up to thousands of times per second. An applied perpendicular tap causes the glass pane to bend away (backward) from the applied tap and then return (forward) at its natural lateral movement rate, which is primarily dependant on the glass pane dimensions, thickness, resilience and edge mounting. A further variable can be attributed to the location of the tap, as well as the temperature of the glass pane. Using an assumed rate of 70 times a second, with a time period of about 14 ms (milliseconds), the total time of its bending backward from rest position would be approximately 7 ms and the total time of bending forward would also be approximately 7 ms.
The majority of the energy imparted by a tap to the outer glass pane is generally perpendicular to it and provides a resulting natural glass flexing movement. In the preferred embodiment the initial rearward deflection caused by the tap is transferred to the inner glass pane having a number of spaced apart piezo sensors affixed thereto, each with a suspended inertia mass and its resilient disc as its reference. The piezo sensors each produce a signal caused by the initial lateral glass movement connected to its first portion in relationship to its reference mass attached to its second portion. The initial motion is stored in the flexing of the piezo's resilient disc relative to its suspended reference mass and provides a reciprocating rate established by the mass and the flexing of the resilient piezo disc. The reciprocating rate is designed to further differentiate from other glass pane movements that may occur.
An object at rest tends to remain at rest, and an object in motion tends to remain in motion (in a straight line). This is also known as the law of inertia. A change in state (rest, or motion) is called acceleration a, which is proportional to the net force Fnet applied to the An object at rest tends to remain at rest, and an object in motion tends to remain in motion (in a straight line). This is also known as the law of inertia. A change in state (rest, or motion) is called acceleration a, which is proportional to the net force Fnet applied to the object from outside: Fnet=m a. The proportionality “constant” m is what physicists call mass. For every action (a force applied to an object from the outside) there is always an equal-and-opposite reaction (the object pushes back on whatever pushed on it).
Newton's Second Law essentially defines mass: it is the numerical size of an object's inertia; that intrinsic property of matter which makes it resist to being accelerated. The more mass an object has, the less acceleration it will have when pushed or pulled by a given size of force. The amount of mass is a measure also of the quantity of matter that makes up an object. The more mass (more matter) in an object, the harder it is to get it moving and the harder it is to stop it once it is moving. The translational inertia is just another name for mass. We can define translational inertia, m, as follows: translational inertia, m, is a measure of an object to a change in its motion.
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The same methods work very well when only one glass pane is used for viewing items to be selected by a user, such as in a non refrigerated vendor, and is anticipated. Also anticipated is the use of any of the taught methods and apparatus disclosed which would include the optional use of the prior art product entry methods and apparatus.
The present application claims priority to Provisional Application Ser. No. 61/034,483, filed on Mar. 6, 2008. The contents of this application are incorporated herein by reference.
Number | Date | Country | |
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61034483 | Mar 2008 | US |