The disclosure herein generally relates to a system, apparatus, and method for determining a combination of cosmetic materials which can be blended and dispensed for a particular user.
In an embodiment, an apparatus is provided for dispensing cosmetic material, comprising: a dispensing device configured to receive a plurality of cartridges that each contain a cosmetic material and to dispense a specified amount of the cosmetic material from each cartridge onto a dispensing surface from a respective outlet that corresponds to each cartridge, wherein the dispensing surface includes at least one partition that partitions the dispensing surface into a plurality of compartments each corresponding to a region surrounding at least one of the respective outlets.
In an embodiment, each compartment of the plurality of compartments corresponds to a separate type of cosmetic material.
In an embodiment, the dispensing surface that includes the at least one partition is removable.
In an embodiment, at least one compartment corresponding to a region surrounding at least two respective outlets.
In an embodiment, the dispensing surface is configured to rotate while the cartridges stay in a fixed position.
In an embodiment, the dispensing surface wherein at least one of the compartments are made of a hydrophilic or hydrophobic material.
In an embodiment, the apparatus is configured to transmit information about the plurality of compartments to an external device.
In an embodiment, the dispensing surface includes an embedded object configured to be sensed by a detection device included in the dispensing device, and the dispensing device is configured to transmit the information about the plurality of compartments and the specific current position of the plurality of compartments to the external device based on the sensed embedded object.
In an embodiment, the embedded object is a near field communication (NFC) tag and the detection device is an NFC reader.
In an embodiment, the dispensing surface includes a visible code placed at a predetermined position on the dispensing surface, wherein the code is configured to have information encoded thereon about the plurality of compartments, the external device is configured to read the code via an image captured by an image capturing device and detect the specific current position of the plurality of compartments based on a current position of the code that is detected in the captured image.
In an embodiment, at least one of the compartments is configured to receive a lid.
The patent or application file contains at least one drawing executed in color. A more complete appreciation of the disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:
In the drawings, like reference numerals designate identical or corresponding parts throughout the several views. Further, as used herein, the words “a”, “an” and the like generally carry a meaning of “one or more”, unless stated otherwise.
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views.
Selecting cosmetic formulations, and component cosmetic materials to formulate cosmetic formulations, is a common activity often relying on subjective decision making and manual input. There are a wide variety of available cosmetic materials, and countless combinations and permutations of possible cosmetic formulations.
For each occasion where cosmetic formulations are used, subjective decisions are often made by an end user of cosmetics to produce satisfactory cosmetic formulations. Outcomes are generally the result of experimentation, perhaps requiring multiple iterations to produce a satisfactory outcome. Partly due to limited awareness of specific traits of the base cosmetic materials and necessary proportions, resulting cosmetic formulations may lack precision. The repeatability of producing a specific cosmetic formulation is thus difficult to accomplish. The below embodiments address these problems in the conventional art.
Specifically, the below description relates to an eco-system for enabling skincare and make a formula personalization system for use at home which is based on a specialized dispensing device that allows ingredients for a cosmetic product to be instantly blended into a user's preferred end result and then conveniently transported for portability.
The system shown in the below is a first-of-its-kind, AI-powered 3-in-1 device for personalized at-home skincare, foundation, and liquid lipstick. The device and its corresponding app assess users' individual skin and local environmental data to create and deliver personalized, on-the-spot skincare and cosmetic formulas that optimize for increasing levels of personalization over time.
The overall eco-system features an AI-enabled, motorized cartridge system as described above that creates personalized skincare and cosmetics formulas in four steps. The device creates personalized skin serums through the following process:
1. Personal skin analysis: The user takes a photo with a smartphone camera and opens an app on the smartphone. The app uses AI to analyze the user's overall skin condition, assessing deep wrinkles, fine lines, dark spots, lack of firmness, pore visibility, and lack of radiance.
2. Environmental assessment: The app (and/or a separate cloud computing platform) assesses local environmental conditions that can influence the state of the user's skin, including weather, temperature, humidity, UV index, air quality, and pollen.
3. Product preference: The user then enters specific skincare concerns, like fine lines, wrinkles, dark spots, rough skin texture and dullness into the app.
4. Custom formulation and dispensing: A personalized blend of high-performance skincare is then dispensed in a portioned, single dose at the top of the device.
The motor system, located at the top of the device, moves and compresses the formula from the cartridges at the base of the machine in an upward motion to the dispensing tray above for a clean application.
With regular use, the AI platform can assess the appearance of a user's skin over time, helping users identify what is working, and calibrating future formulas. The AI-powered system can optimize the efficacy of personalized formulas. By taking photos regularly, users enable the smart system to recognize the formulas' effects, and adjust the dosage of active ingredients accordingly. That said, the user can override the system recommendations if they are seeking, for example, additional moisturizer.
The skincare system contains active ingredients including AHAs, Vitamins C and E, hyaluronic acid, ferulic acid, retinol, cucumber, thyme, and mulberry.
The cosmetics offerings—for foundation and liquid lipstick—will have the capability to incorporate real-time trend information as well as color-matching technology into its personalized product offerings as described below.
There are three dosing settings for the system described herein. There will be a standard-sized dose (0.7 grams; roughly the size of a pistachio) that users can double or triple with an additional touch.
The device features a detachable mirrored compact so you can take a portioned dose of product with you.
From opening the app and taking a photo of one's face to dispensing product, the user experience with the present system takes about three minutes.
[Dispensing Device]
The controller 150 includes circuitry for distributing power received through the power cord 104, controlling one or more motors 112 to dispense cosmetic material, detecting readings of an optical encoder 192, charging one or more batteries 126, operating any indicators such as the indicator light and button 122, chimes, or other audiovisual signals, sensors such as for detecting availability status, type, and quantity of cosmetic material, and communicating wirelessly with external devices, including circuitry to send and receive signals and data, for example through smart phones and other wireless devices, using a variety of communication protocols, such as Radio Frequency (RF), Bluetooth, Wi-Fi, or cellular.
The inductive plate 176 supports the bottom plate 166, aside from the base 102 and the power cord 104, the remainder of the cosmetic dispenser 100 is disposed atop the bottom plate 166. The gearhousing 170 is disposed above, is connected to, and provides support to internal components of the cosmetic dispenser 100 that are further described by
For example, the upper body section 156 is disposed above the middle body section 155, and the lower body section 154 disposed below the middle body section 155. When connected, the dispenser body 106 attaches to outside of at least one of the lower body section 154, the middle body section 155, and the upper body section 156. The bottom plate 166 is disposed below and connected to the lower body section 154.
Further, a plurality of batteries 126 inside the cosmetic dispenser 100 are electrically connected to the plurality of dispensing assemblies 120 to provide electrical power for the operation of the controller 150, the dispensing assembly 120, the motor 112, and various indicators, such as the indicator light and button 122 (further described in
The controller 150 and a connected device 300 (shown in
The cartridge 114 also has a cartridge key 162 disposed on or near the nozzle 160, is connected near a first end to the cartridge gear 116, is connected near a second end to the bottom plate 166, with a motor gear 124 connected to the motor 112, and the motor gear 124 drivingly connected to the cartridge gear 116. The cartridge 114 and the cartridge gear 116 are held in position by the gearhousing 170 (shown in
Additionally, a detent plunger 146 may be disposed substantially perpendicularly to a longitudinal axis of the cartridge 114 and connected near the second end of the cartridge 114, providing a lateral pressure to a circumferential groove circumferential groove 134 of the cartridge 114, keeping the cartridge 114 in place along the vertical Y-axis, counteracting an opposite force applied by tension to the cartridge 114 by the ejector 140, the ejector spring 142, and an ejector spring pin 144. The ejector 140 is disposed within the cosmetic dispenser 100 and may move substantially parallel to the cartridge 114, and is connected to the ejector spring 142 that is further connected to the ejector spring pin 144. As the cartridge 114 is inserted into the cosmetic dispenser 100, an edge of the ejector 140 contacts an edge near the first end of the cartridge 114. The ejector 140 applies a pressure to the cartridge 114 as the ejector spring 142 stretches with the increasing distance between the stationary ejector spring pin 144 and the ejector 140, as the ejector 140 moves with the cartridge 114 further into the cosmetic dispenser 100. Once the cartridge 114 is inserted to the point that a first end of the detent plunger 146 makes contact with the circumferential groove 134 of the cartridge 114, the motion of the cartridge 114 along the Y-axis is restricted, holding the cartridge 114 in place.
The detent plunger 146 is a mechanism for holding the cartridge 114 in place. The detent plunger 146 moves along an axis substantially perpendicular to that of the major axis of the cartridge 114. A first end of the detent plunger 146 is disposed to make contact with the cartridge 114. A second end is connected to a first end of a detent spring 152, the second end of the detent spring 152 in contact with an inside surface of at least one of the dispenser body 106, the lower body section 154, the middle body section 155, the upper body section 156, or other internal structure. Insertion of the cartridge 114 into the cosmetic dispenser 100 displaces the detent plunger 146 against the detent spring 152, compressing the detent spring 152. Because the contour of the cartridge 114 varies over the length of the cartridge 114, the detent plunger 146, and the detent spring 152 are displaced by varying amounts depending on the position of the cartridge 114 relative to the cosmetic dispenser 100. At a point where the detent plunger 146 contacts the circumferential groove 134 of the cartridge 114, the first end of the detent plunger 146 is able to lock the cartridge 114 in place due to pressure of the detent spring 152 and the geometric relationship between the detent plunger 146 and the circumferential groove 134.
Further, the cartridge 114 is inserted into the cosmetic dispenser 100 through a cartridge through hole 172 of the bottom plate 166. The cartridge through hole 172 has a base key cutout 165 (
The motor gear 124 may be a spur gear that includes a key cutout 163 (
The cartridge 114 contains and dispenses an amount of cosmetic material into the compact 108 as needed (further described by
An amount of cosmetic material is released from the cartridge 114 through the nozzle 160 by a first rotational motion of the first end with respect to the second end of the cartridge 114. Rotational motion of the first end of the cartridge 114 in a second direction, opposite of the first rotational motion, may close the nozzle 160 of the cartridge 114.
The cartridge gear 116 actuates the nozzle 160 of the cartridge 114 that is attached to a hollow cartridge lead screw 202 within the cartridge 114. Rotation of the cartridge lead screw 202 proportionately displaces a cartridge piston 200 that forces an amount of cosmetic material through the cartridge lead screw 202 and out the nozzle 160 of the cartridge 114. The amount of cosmetic material released during an opening and closing operation of the nozzle 160 is a function of the displacement of the cartridge lead screw 202, which is dependent upon the rotational displacement of the cartridge gear 116. Rotation of the motor 112 rotates the respective motor gear 124 and the cartridge gear 116. The controller 150 detects the relative motion of the cartridge gear 116 using the optical encoder 192 to count a number of cartridge gear slots 148 that pass the optical encoder 192 as the cartridge gear 116 rotates, and the direction of rotation of the cartridge gear 116. A specific unit of measure of cosmetic material is a dose unit dose unit 118.
In one example, the pitch of the cartridge lead screw 202 is about 1 mm, with one full rotation of the cartridge lead screw 202 dispensing about 1 mL of cosmetic material from the cartridge 114.
In another example, due to the shape of the cartridge key 162 of the cartridge 114 the circumferential groove 134 may be a notch or a groove about a portion of the circumference of the cartridge 114, rather than extend fully around the perimeter of the cartridge 114 to secure the cartridge 114 to the detent plunger 146 in substantially the same manner.
The bottom plate 166 has a plurality of cartridge through holes 172 to allow for the insertion, removal, and securement of the plurality of cartridges 114. Each cartridge through hole 172 includes a base key cutout 165, and the shape of the base key cutout 165 corresponds to the shape of the base key 164 of each cartridge 114 to prevent rotational motion of the second end of the cartridge 114, the portion in contact with the bottom plate 166, when the cartridge 114 is installed in the cosmetic dispenser 100.
Further, the bottom plate 166 has contact pins 174 (shown in
The compact 108 is connected to the manifold 130, the manifold 130 connected to and disposed above the gearhousing 170, further disposed within the dispenser body 106 of the cosmetic dispenser 100, and the compact 108 is disposed above both the manifold 130 and the dispenser body 106. The manifold 130 includes one manifold through hole 132 for each cartridge 114 in the cosmetic dispenser 100, and the manifold 130 is disposed such that each manifold through hole 132 corresponds to and is connected to a compact base through hole 136 of the bottom lid 184. Further, each manifold through hole 132 of the manifold 130 corresponds to and is disposed above a gearhousing cartridge hole 178 of the gearhousing 170, providing a passage by which cosmetic material can be dispensed from the nozzle 160 of each cartridge 114 through the manifold 130, the bottom lid 184, and into the compact base 182.
The compact 108 may have a form such that there is only one orientation by which the compact 108 can connect to the cosmetic dispenser 100. In another example, it may be that the form of the compact 108 can connect to the compact 108 in more than one orientation.
Further, cosmetic material dispensed into the compact 108 may be prevented from flowing back out by use of a one way duckbill valve 194 (not shown) disposed within each of the compact base through holes 136 in the bottom lid 184 of the compact 108.
In one example, the compact base 182, the plurality of mounting magnets 196a-196c, a first half of the plurality of lid magnets 188b and 188d, and a first half the plurality of hinge magnets 186b and 186d, are disposed within the bottom lid 184, with the compact base 182 disposed above. The plurality of mounting magnets 196a-196c are disposed to magnetically connect the compact 108 to the cosmetic dispensing device 100, for example by connecting to the manifold 130 (
A second half of the plurality of lid magnets 188a and 188c are disposed within a side of the top lid 180, and a second half of the plurality of hinge magnets 186a and 186c are disposed within a side of the top lid 180. The hinge magnets 186b and 186d are disposed within a side of the bottom lid 184 such that they may be in contact with corresponding hinge magnets 186a and 186c in at least two planes, depending on a relative position between the top lid 180 and the bottom lid 184. The hinge magnets 186a and 186b have opposite magnetic polarity, as do the respective pairs of hinge magnets 186c and 186d, the lid magnets 188a and 188b, and the lid magnets 188c and 188d.
The plurality of 196 and the plurality of lid magnets 188a-188d may be disposed such that the plurality of bottom lid through holes 138 disposed in the compact base 182 are unobstructed to allow cosmetic material to flow from each of the cartridges 114 into the compact 108 as cosmetic material is dispensed.
In a case where the compact 108 is in an open position, the top lid 180 and the bottom lid 184 are positioned approximately in perpendicular planes, the hinge magnets 186a and 186c magnetically connected to the hinge magnets 186b and 186d, respectively. The magnetic force between each pair of the hinge magnets 186a and 186b and the hinge magnets 186c and 186d is sufficient to hold the top lid 180 in position relative to the bottom lid 184.
In a case where the compact 108 is in a closed position, the top lid 180 and the bottom lid 184 are positioned approximately in parallel planes, the hinge magnets 186a and 186c magnetically connected to the hinge magnets 186b and 186d, respectively, and the lid magnets 188a and 188c are disposed in corresponding positions, and magnetically connected with the lid magnets 188b and 188d, respectively, the magnetic connection between the pairs of hinge magnets 186a and 186b and the hinge magnets 186c and 186d, and between the pair of lid magnets 188a and 188b, and the pair of lid magnets 188c and 188d, sufficient to keep the top lid 180 connected to the bottom lid 184 in a closed position.
Since the top lid 180 is connected to the bottom lid 184 magnetically, the top lid 180 may be entirely removable from the bottom lid 184. Further, it may also be able to connect with the bottom lid 184 in a closed position in more than one orientation about the x-z plane, depending on the disposition of the plurality of the hinge magnets 186a-186d and the lid magnets 188a-188d within the top lid 180 and the bottom lid 184. Further, the top lid 180 may be able to pivot about the bottom lid 184, or vice versa, opening or closing about more than one axis, such as about the x-axis or the z-axis.
Alternatively, the plurality of mounting magnets 196a-196c may be substituted by one mounting magnet 196 of sufficient strength to secure the compact 108 to the cosmetic dispensing device 100.
Alternatively, the plurality of hinge magnets 186a-186d may be substituted by one hinge magnet 186a of sufficient strength in the top lid 180 and by one hinge magnet 186b of sufficient strength in the bottom lid 184 to secure one side of the top lid 180 to the bottom lid 184 with the compact 108 in an open or a closed position.
Alternatively, the plurality of lid magnets 188a-188d may be substituted by one lid magnet 188a of sufficient strength in the top lid 180 and by one lid magnet 188b of sufficient strength in the bottom lid 184 to secure one side of the top lid 180 to the bottom lid 184 with the compact 108 in a closed position.
The optional step 923 of detecting a quantity of material in each of a plurality of cartridges 114 may include, for example, step 923a detecting a quantity of material of a cartridge A, step 923b detecting a quantity of material of a cartridge B, and step 923c detecting a quantity of material of a cartridge C, for example based on total net displacement (rotation) of the cartridge gear 116 detected by the optical encoder 192 since installation of each cartridge 114.
The optional step 924 of detecting at least one material characteristic in each of a plurality of cartridges 114 may include, for example, step 924a detecting at least one material characteristic of a cartridge A, step 924b detecting at least one material characteristic of a cartridge B, and step 924c detecting at least one material characteristic of a cartridge C. Material characteristics may include at least one from the set of consisting of color, texture, sheen, moisture, nutrient content, and chemical formulation. This detection may be performed based on a near field sensor disposed in the dispenser 100 which detects an RFID tag on the cartridge that stores information of the contents of the cartridge according to methods well understood in the art. Alternative methods of detection may be used such as bar code detection of a bar code printed on the cartridge, or detection using methods well understood in the art. The step of detecting the at least one material characteristic in each of the cartridges may be performed before the optional step of detecting the quantity of cosmetic material in each cartridge.
Further, process S920 may include optional step 926 for reporting information that may be derived from historical usage data, of the user or aggregated across groups of users, such as which cartridge 114 within the cosmetic dispenser 100 is anticipated to be depleted of cosmetic material first and by when.
A step 942d may be based on a user selecting from a set of cosmetic formulations that are possible for the types and quantities of cosmetic material present within the cosmetic dispenser 100, or a step 942c allows the user to choose from a larger set of cosmetic material inventory 204 that is possible for types and quantities of cosmetic materials the cosmetic dispenser 100 is capable of using.
In another example, a step 943 of process S940 includes allowing a user to choose a desired dose unit 118. Varying the dose unit 118 can change the set of available cosmetic formulations from within the cosmetic dispenser 100 if a greater amount of one or more cosmetic materials is needed than is available to dispense a specific quantity of dose unit 118 for a specific cosmetic formulation.
For example, if cartridge A contains yellow cosmetic material, cartridge B contains red cosmetic material, and cartridge C contains green cosmetic material, and there is only one dose unit 118 of cartridge A remaining, the user would not be able to choose to dispense any combination of dose units 118 and cosmetic formulation that requires more than one dose unit 118 of yellow cosmetic material.
Further, the process S940 may include a step 942a for the user to select a cosmetic formulation based on matching of a photo, a step 942b for the user to select a cosmetic formulation based on recommendations, or selecting a cosmetic formulation based on another process. U.S. Pat. No. 8,634,640, describes a method for selecting a color from an image or picture in a camera or electronic device, and using color reference data to substantially match the color, and is hereby incorporated as reference in its entirety.
In another embodiment, a skin diagnosis (sometimes referred herein as a skin profile) may be performed for providing a recommended plurality of predetermined colors for the user to select based on an analysis of the user's skin features. The skin diagnosis determines an appropriate color for the user based on an imaging operation performed on the user's face. Examples of known skin diagnosis tools in the art are: Lancome Diagnos ABS, HR Skinscope, Biotherm Bluesmart, Kiehl's Skinprofiler V.0, CA Dermanalyzer, and the Vichy Vichyconsult.
For cosmetic formulations that are possible but not available based on the results of the detecting process S920, the cosmetic dispenser 100 may communicate to the user what cosmetic materials are necessary to dispense such cosmetic formulations.
In one example, in step 944 the user selects a dose unit 118 of a cosmetic formulation presently unavailable. Step 944 may determine what cosmetic materials, such as what type of cartridges 114 are needed to mix and dispense the selected cosmetic formulation.
In another example, step 944 may determine what additional cosmetic formulations may become available if a specific cartridge 114 is replaced with a full but otherwise identical cartridge 114.
In another example, step 944 may determine what additional cosmetic formulations may become available if a cartridge 114 is replaced with another cartridge 114 containing different cosmetic material.
Step 945 determines whether to proceed to step 947 to prompt the user to confirm and proceed with dispensing a cosmetic formulation or to proceed to step 946 to report what cartridge or cartridges 114 are needed to dispense the desired cosmetic formulation, based on the outcome of step 944.
After the dispensing process S960 is completed, the user may perform the process S980 of mixing the released cosmetic material manually, producing the requested cosmetic formulation.
The connected device 300 may be a personal computer (PC), a laptop computer, a PDA (Personal Digital Assistants), a smart phone, a tablet device, a UMPC (Ultra Mobile Personal Computer), a net-book, or a notebook type personal computer. In the below examples, the connected device 300 is assumed to be a tablet device, such as an Apple iPad.
The connected device 300 is capable of performing wireless communication with the cosmetic dispenser 100 by way of a wireless communication interface circuitry 774 on the cosmetic dispenser 100. However, connected device 300 is also capable of having a wired connection to the cosmetic dispenser 100 by way of a USB interface 776 on the apparatus 100. Additionally, each device, including the cosmetic dispenser 100, may communicate with each other and the external one or more devices through an internet connection via an 802.11 wireless connection to a wireless internet access point, or a physical connection to the internet access point, such as through an Ethernet interface. Each connected device 300 is capable of performing wireless communication with other devices, such as through a Bluetooth connection or other wireless means as well.
The connected device 300 is configured to receive information from a user for use in generating a cosmetic formulation that will be used by the cosmetic dispenser 100 to dispense cosmetic material into the compact 108.
In an embodiment, circuitry includes, among other things, one or more computing devices such as a processor (e.g., a microprocessor, a quantum processor, qubit processor, etc.), a central processing unit (CPU), a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable gate array (FPGA), or the like, or any combinations thereof, and can include discrete digital or analog circuit elements or electronics, or combinations thereof.
In an embodiment, a module includes one or more ASICs having a plurality of predefined logic components.
In an embodiment, a module includes one or more FPGAs, each having a plurality of programmable logic components.
In an embodiment, circuitry includes one or more components operably coupled (e.g., communicatively, electromagnetically, magnetically, ultrasonically, optically, inductively, electrically, capacitively coupled, wirelessly coupled, or the like) to each other.
In an embodiment, circuitry includes one or more remotely located components.
In an embodiment, remotely located components are operably coupled, for example, via wireless communication, such as with a connected device 300.
In an embodiment, remotely located components are operably coupled, for example, via one or more communication modules, receivers, transmitters, transceivers, or the like.
In an embodiment, any of the CPU 710 or other components shown in
In an embodiment, memory is coupled to, for example, one or more computing devices by one or more instructions, information, or power buses.
In an embodiment, circuitry includes one or more computer-readable media drives, interface sockets, Universal Serial Bus (USB) ports, memory card slots, or the like, and one or more input/output components such as, for example, a graphical user interface, a display, a keyboard, a keypad, a trackball, a joystick, a touch-screen, a mouse, a switch, a dial, or the like, and any other peripheral device.
In an embodiment, a module includes one or more user input/output components that are operably coupled to at least one computing device configured to control (electrical, electromechanical, software-implemented, firmware implemented, or other control, or combinations thereof) at least one parameter associated with, for example, determining one or more tissue thermal properties responsive to detected shifts in turn-ON voltage.
In an embodiment, circuitry includes a computer-readable media drive or memory slot that is configured to accept signal-bearing medium (e.g., computer-readable memory media, computer-readable recording media, or the like).
In an embodiment, a program for causing a system to execute any of the disclosed methods can be stored on, for example, a computer-readable recording medium, a signal-bearing medium, or the like. Non-limiting examples of signal-bearing media include a recordable type medium such as a magnetic tape, floppy disk, a hard disk drive, a Compact Disc (CD), a Digital Video Disk (DVD), Blu-Ray Disc, a digital tape, a computer memory, or the like, as well as transmission type medium such as a digital or an analog communication medium (e.g., a fiber optic cable, a waveguide, a wired communications link, a wireless communication link (e.g., receiver, transmitter, transceiver, transmission logic, reception logic, etc.). Further non-limiting examples of signal-bearing media include, but are not limited to, DVD-ROM, DVD-RAM, DVD+RW, DVD-RW, DVD-R, DVD+R, CD-ROM, Super Audio CD, CD-R, CD+R, CD+RW, CD-RW, Video Compact Discs, Super Video Discs, flash memory, magnetic tape, magneto-optic disk, MINIDISC, non-volatile memory card, EEPROM, optical disk, optical storage, RAM, ROM, system memory, web server, or the like.
In an embodiment, circuitry includes acoustic transducers, electroacoustic transducers, electrochemical transducers, electromagnetic transducers, electromechanical transducers, electrostatic transducers, photoelectric transducers, radio-acoustic transducers, thermoelectric transducers, or ultrasonic transducers.
In an embodiment, circuitry includes electrical circuitry operably coupled with a transducer (e.g., an actuator, a motor, a piezoelectric crystal, a Micro Electro Mechanical System (MEMS), etc.).
In an embodiment, circuitry includes electrical circuitry having at least one discrete electrical circuit, electrical circuitry having at least one integrated circuit, or electrical circuitry having at least one application specific integrated circuit.
In an embodiment, circuitry includes electrical circuitry forming a general purpose computing device configured by a computer program (e.g., a general purpose computer configured by a computer program which at least partially carries out processes and/or devices described herein, or a microprocessor configured by a computer program which at least partially carries out processes and/or devices described herein), electrical circuitry forming a memory device (e.g., forms of memory (e.g., random access, flash, read only, etc.)), electrical circuitry forming a communications device (e.g., a modem, communications switch, optical-electrical equipment, etc.), and/or any non-electrical analog thereto, such as optical or other analogs.
[Personalized Cosmetic Ecosystem]
Usage of the smartphone application itself involves the user actually making selections that lead to the determination of a color, and performing interactive communication with the dispenser, such as sending the recipe to the dispenser and tracking the status of the dispenser (such as inventory and remaining volume of the cartridges in the dispenser). The smartphone application also performs interactive communication with the cloud platform. For instance, the smartphone application can receive the selection of relevant looks are described above, and it can also provide direct user feedback from the user on the looks the cloud platform previously sent and it can notify the cloud platform on the colors and recipes actually selected by the user and dispensed by the dispenser. Such feedback can provide a form of machine learning to the cloud platform and improve the algorithms used by the cloud platform.
[Personalized Lipstick Ecosystem]
The setup inputs are used during regular usage of the app on the smartphone, but they are also transmitted to a cloud platform, which may be an external server device that is connected via the Internet.
The actual usage of the smartphone app (1720) includes selecting a mode for lipstick selection. In the present example, the modes include a mode for selecting a social media trend recommendation by algorithms that are executed in the cloud platform (discussed later in more detail). Another mode allows the user to create their own lipstick color using a wide variety of color options.
Another mode may allow the user to match a lipstick color to their “look” based on selfie picture. In this example, the shade and finish selection on proposed picture is extracted. The user can virtually try on the lipstick in real time, the user can adjust the color presented. When the user is satisfied with the color, the user can touch a button displayed on the app to dispense the formula and an internal neural network will decompose the color requested into different color cartridge dose. After the recipe is sent to the dispenser and the lipstick shade is dispensed, the user can apply the lipstick.
Following use of the lipstick, the user can use the app to provide a feedback if she/he liked the rendering or not. The user can also save her favorite look and color to reuse later on, and the user can share the look and color on the web via a social media platform.
The cloud platform implements functions shown in 1730, such as a workflow of remote algorithms and an improvement process.
In the workflow performed by the cloud platform, social media network personal accounts (influencers, most trending looks) may be scraped for data related to lipstick colors. The cloud platform may perform analyzing of one or more collected images to extract average make up color (lip, foundation, hair color) by using a deep learning algorithm to segment lip finishes of make up. For instance, the cloud platform may accomplish this by first detecting lips in a plurality of images using a known technique in the art (such as that described in U.S. Pat. No. 5,805,745, which is incorporated herein by reference). The cloud platform may then perform comparisons of an extracted color with colors most liked by one or more communities of users while also taking into account the setup inputs of the user received from the user's smartphone device. Taking into account all of the collected data, the final step is for the cloud platform to send to the user the results of the analysis in the form of the above-noted selection of relevant looks.
In the improvement process performed by the cloud platform and the smartphone app, the user can save her favorites looks and “like” the popular color to enrich the scraping algorithms for a relevant recommendation at a later time. The cloud platform can further aggregate all of the users' feedback, and the platform can send to new users the most trending area per localization.
The dispenser operations in block 1740 are already described in detail above, but they are summarized as follows. The dispenser receives a command to dispense a certain proportion of each cartridge. The dispenser dispenses on the top part and user can mix it to obtain the desired color. The dispenser send back inventory left of formula to the consumer app to make sure only dispensable colors are available in the UI when the user makes a selection.
Step 1820 shows an example of a display when the mode is chosen for selecting a trending look powered by an AI algorithm of the cloud platform. Step 1820 also shows that a menu is provided at the bottom of the interface to allow the user to switch between the above-described modes.
Step 1830 shows an example of a display when the user has selected a potential shade and is allowed to adjust the shade using an appropriate adjusting mechanism such as a color palette or slider. The shade can be shown on the selfie of the user.
Step 1840 shows that after a color is ultimately selected by the user, the color is decomposed into a combination of the available colors contained in the cartridges of the dispensing device, and then the recipe is transmitted to the dispensing device for dispensing.
[Personalized Skincare Ecosystem]
The setup inputs are used during regular usage of the app on the smartphone, but they are also transmitted to a cloud platform, which may be an external server device that is connected via the Internet.
The actual usage of the smartphone app (1920) includes collecting environmental data based on geolocation and combine it with a smartphone diagnosis assessing clinical signs (wrinkles, dark spots, firmness, pores, fine lines, dullness).
The user can also collect data of a UV sensor, such as a wearable UV sensor as described in U.S. Pat. No. 10,060,787, incorporated herein by reference, that will actually give precise measurement of the cumulated UV exposure received. Based on historical data of skin assessment and environmental factor, the app will process the ideal formulation to fight against your skin aging signs and prevent from environment. When the user is satisfied with the formulation, the user can touch a button displayed on the app to dispense the formulation and an internal neural network will decompose the formulation requested into different cartridge ingredients. After the recipe is sent to the dispenser and the formulation is dispensed, the user can apply the formulation. The user can provide feedback on their favorite formulations for a specific period of time.
The cloud platform implements functions shown in 1930, such as a workflow of remote algorithms and an improvement process. In the workflow performed by the cloud platform, based on environmental forecast on UV, pollen, pollution, temperature, specific notifications are sent to the app user to adjust the recipe. For instance, there is a known correlation between environmental conditions and skin aging (see “Assessing the impact of an aerial chronic urban pollution (UP) on some facial signs of differently-aged Chinese men” at www.researchgate.net, and “The skin aging exposome” at www.jdsjournal.com). Additionally, giving an input of the geolocation of the user, which can provide an air quality determination using a tool such as Breezometer™ and a local UV index forecast (or the UV exposure can be obtained based on a UV sensor described above), the cloud platform can adjust the recipe to address environmental factors such as UV exposure and air quality. For instance,
In the improvement process performed by the cloud platform and the smartphone app, the user can save their favorites recipes that are the most efficient overtime or the best sensation on skin. The user can also share with the community their recipes.
The cloud platform can further aggregate all of the users' feedback, and the platform can send to new users the most trending formulizations area per localization.
The dispenser operations in block 1940 are already described in detail above, but they are summarized as follows. The dispenser receives a command to dispense a certain proportion of each cartridge. The dispenser dispenses on the top part and user can mix it to obtain the desired color. The dispenser send back inventory left of formula to the consumer app to make sure only dispensable ingredients are available in the UI when the user makes a selection.
Step 2030 shows the analysis results for one more of the skin features which are analyzed. The results may be shown as a score, which may be relative to people in the user's age range. For instance, each of the skin features may be presented on a five point scale, and features which represent a worse score than an average score may be highlighted as a priority for the user, while features which are better than the average may be presented as a strength.
Step 2040 shows that the app may present a recommended skincare formulation (“blend’) which addresses the user's priority skincare concerns while taking into account the current environmental conditions. After the formulation is ultimately selected by the user, the formulation is decomposed into a combination of the available colors contained in the cartridges of the dispensing device, and then the recipe is transmitted to the dispensing device for dispensing at step 2050.
[Personalized Foundation Ecosystem]
The setup inputs are used during regular usage of the app on the smartphone, but they are also transmitted to a cloud platform, which may be an external server device that is connected via the Internet.
The actual usage of the smartphone app (2120) includes collecting environmental data based on geolocation and combine it with a smartphone diagnosis assessing the skintone of the user. While methods of determining a user's skintone for matching a foundation are known in the art, a method below related to a deep learning method will be discussed in detail. Depending on the user's skin condition, the app may determine to merge skincare actives with the foundation like SPF when the environmental conditions are not optimal. The app makes a determination based on the period of the year and the tanning level of the person to slightly adjust the foundation color to follow the skintone evolution. When the color is not perfecting the matching process, the user can send a feedback to the cloud to improve remotely the algorithms. In certain cases, the user may want to use the device to adjust primer color so as to achieve specific make up strategy by layering different colors.
The cloud platform implements functions shown in 2130, such as a workflow of remote algorithms and an improvement process. In the workflow performed by the cloud platform, based on environmental forecast on UV, pollen, pollution, temperature, specific notifications are sent to the app user to adjust the recipe by adding SPF. The cloud platform may shift the master skintone formula for the user that is sent when the tanning level of the consumer is different from the initial diagnosis.
In the improvement process performed by the cloud platform and the smartphone app, the user can save their favorites recipes that are the most efficient overtime or the best sensation on skin. The user can also share with the community their recipes. The cloud platform can further aggregate all of the users' feedback, and the platform can send to new users the most trending formulizations area per localization.
The dispenser operations in block 2140 are already described in detail above, but they are summarized as follows. The dispenser receives a command to dispense a certain proportion of each cartridge. The dispenser dispenses on the top part and user can mix it to obtain the desired color. The dispenser send back inventory left of formula to the consumer app to make sure only dispensable ingredients are available in the UI when the user makes a selection.
In step 2230, the app may present a recommended foundation (“blend’) which matches the user's skintone while taking into account the current environmental conditions. After the foundation is ultimately selected by the user, the foundation is decomposed into a combination of the available ingredients contained in the cartridges of the dispensing device, and then the recipe is transmitted to the dispensing device for dispensing at step 2240.
[Smart Swappable Cartridge System]
The dispensing device described above allows for swapping the consumable cartridges in a smart and efficient manner. The cartridges (consumables) used in the above-described dispensing device are preferably managed in sets (such as sets of three cartridges). For instance there could be separate sets of cartridges for each of the lipstick, skincare, and foundation applications described above. In the system, consumables sets equipped with smart chip or an electronic device configured to perform data storage and transmission/reception (such as NFC, RFID, or a contact chip). In the following description an NFC (Near Field Communication) tag will be mentioned, but the claims are not limiting to this example. Each cartridge has a different cosmetic attributes and a unique formula identifier that can identify attributes such as Shade/finish, Texture, and Skin/hair benefits. Attributes are stored on the integrated circuit at production and signed with an asymmetrical cryptographic algorithm.
As will be discussed in detail below, the NFC tag applied to the cartridges ensures the management of color universe for the user, multi device use cases, and traceability. The tag will have two zones of memory: one zone for the production data (encoded during the filling process); and one zone for the use where the device will encode the usage and follow up quantities. Additionally, the following security mechanism have been implemented: (i) ensure the non-modification of production data: sector edition are protected by password (secret password); (ii) ensure the non-duplication of the cartridge data in case of diversion: adding a signature mechanism using UIID (unique id of the tag, the data encoded, the secret key of the manufacture). The app using the device to read cartridge will then check that the signature comes from the manufacturing entity before allowing dispensing.
Accordingly, the priming process can detect when a new cartridge has been installed and it allows proper engagement with the plunger of the dispensing device and the formula contained in the cartridge so that a proper dose can be dispensed when an actual blend is being created.
Additionally, by detecting the exact cartridges that are installed, the set of cartridges (such as the set of three cartridges) can be determined, and the color attributes (or skincare attributes) that are possible with the current set are automatically updated on the app. Also, the app can perform consumable management by suggesting or automatically performing cleaning of the pipes when a cartridge is changed. The app can further adapt the formula universe in the user interface function depending on what type of set of cartridges is installed.
Furthermore, the app state machine can detect inconsistent sets or missing cartridges. It can propose to buy missing set to reach a result. It can automatically detect expiration dates of any cartridges. Also, since safety information is stored on the cartridge, it allows natively multi-user and multi-device capability since each separate user smartphone will detect the information on the cartridge independently.
During priming, the cartridges can also be authenticated. A 32 bit hash code is generated at production using a secret key of the manufacturer and the code is encoded onto the NFC tag of the cartridge. The smartphone includes a hardcoded secret key, which may be included in a software developer kit (SDK), to verify the hash code upon reading data from the NFC tag transmitted from the dispensing device. The smartphone may also be hardcoded with the secret key if possible. A Unique Item Identification (UIID) tag may also be physically added to the cartridge or NFC tag (in the form of a barcode for example) and read by the dispending device. If the process of authentication of the cartridge fails, the dispensing device may transmit the notification to the smartphone.
In some rare cases, the user may encounter a cartridge where the NFC tag is not read by the machine (encoding error, tag destruction, device not in range, other defect). In this case the user has to be still able to dispense formula and use his device as normal as possible. To ensure this tolerant default mode, a recovery cartridge mode requiring the user to enter information of the cartridge will take over the operation. The application relying on THE SDK will then create a virtual cartridge to continue the algorithm to dispense. This automatic triggered recovery mode will be turned off at the moment a new cartridge is inserted or the NFC is again in range.
[Dispensing and Auto-Cleansing System]
As the above-described system includes swapping cartridges of many different types, a special cleaning mechanism that integrates with the structure of the removable compact has been developed to provide a unique cleaning capability to enhance the user experience.
It can be seen that the retractable plate includes a side surface that is bent at approximately 90 degrees to the top surface, which allows the plate to move downward into a slide groove 3050 of the body of the dispensing device.
With the above retractable plate mechanism in place, the method of cleaning the surface of the compact will be described with reference to
Examples of the cleaning formula include soap, alcohol, or other known cleaning solutions.
Each position described above may be achieved by manual force provided by the user. Alternatively, each position may be achieved by electromechanical means such as a motorized actuator device as is understood in the art. The cleaning formula may be manually wiped, spread, and/or brushed and removed by the user.
[Smart Personalized Compartment System]
In an embodiment, the tray is circular and can be rotated to allow different combinations of product into a compartment without swapping cartridges in the dispensing device. The type of compartmentalized tray is saved in the companion mobile application to get personalized recommendations suitable based on compartment chosen.
In an alternative embodiment to the tray shown in
As depicted in
[Remote Consultation]
The communication between the BA device 3610 and the consumer device 3620 may be in the form a call, chat session, or video conference.
The BA device 3610 executes a remote application 3611 while performing communication with the consumer device 3620. The remote application 3611 performs functions related to collecting and displaying consumer data for the BA and receiving inputs recommendations and settings from the BA.
The consumer device 3620 executes an application of a user interface (App UI) 3621 which allows the consumer to trigger the communication with the BA, receive inputs to form the consumer data, and to perform communication with the dispensing device 3630.
The dispensing device 3630 is configured to dispense a cosmetic formula based on instructions received from the consumer device 3620.
The dispensing device can be used for a variety of cosmetic applications already discussed above. Further dispensing operations may be performed related to dispensing of nail polish directly onto the user's nails with a ultraviolet (UV) lamp provided to accelerate drying of the nail polish. Other types of cosmetic formulations may be provided, such as liquid eye shadow; dry cosmetics; and hair, skin, body, and sun care products. This list is not limited, and make-up of all categories may be used in the above-described system.
In Step 2, consumer data is collected.
Diagnosis data may be data collected based on images taken with the camera of the consumer device (to be discussed in more detail later), or it may be direct answers to questions from the BA. The questions may include a questionnaire, a grading of the user's priorities, or it may include status questions, such as hormonal cycle, allergies, medical conditions, or others.
Biological data may be actual biological samples provided from the user, or described by the user, such as protein samples; microbiome samples; hair, skin, nail samples; and sebum, dandruff, and sweat samples. Biological samples can be collected, for example, by using specific adhesive tapes that collect stratum corneum skin/scalp cells to extract and analyze proteins (Elisa process). Microbiome samples can be collected, for example, by specific using absorbing papers/Q-tips placed on the user's skin surface for several seconds to collect sebum, sweat, hydrolipidic film. Hair samples can be collected as a lock of hair that is cut by the user or some hair including the bulb that is pulled by the user. Nail samples can be cut by the user. These samples may be collected using sampling kits sent to the user's home and sent back for analysis to a mandated laboratory. The data results from the analysis are stored using a Unique Identifier (UI) and transmitted to remote servers.
Environmental data may include information particular to a user's area or habits. Such data may include indoor/outdoor pollution information; water quality; screen time; and commuting habits (such as use of a car, bike, or motorcycle). This information may be collected based on questions or publicly available information.
Social network sharing data may be obtained from monitoring the consumer's interests on social media platforms. This data may include lifestyle, travel, food, and activity interests. This data may be obtained from the BA remote application 3611, or from an external server, after receiving inputs from the user on Internet links to their social media platforms.
Returning to
Based on the possibility that a plural amount of treatments may be used based on the user's skin conditions, different types of skincare ingredients may be dispensing into different compartments of a removable compact device as described above.
Additional features may be determined during the consultation, such as the settings for a UV lamp as noted in the nail gel example described above. The auto-cleansing and priming steps described above may also be determined.
Thus, the foregoing discussion discloses and describes merely exemplary embodiments of the present invention. As will be understood by those skilled in the art, the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Accordingly, the disclosure of the present invention is intended to be illustrative, but not limiting of the scope of the invention, as well as other claims. The disclosure, including any readily discernable variants of the teachings herein, define, in part, the scope of the foregoing claim terminology such that no inventive subject matter is dedicated to the public.