Patent Description:
The present disclosure generally relates to infant care stations, and more specifically to providing open access point indicators for an enclosure of an infant care station.

Some neonates are not physiologically well enough developed to be able to survive without special medical attention. A frequently used medical aid for such infants is the incubator. One objective of the incubator is to provide an environment which will maintain the neonate at a minimum metabolic state thereby permitting as rapid physiological stability as possible. Neonatal incubators create a microenvironment that is thermally neutral where a neonate can minimize energy expenditure. These incubators typically include a humidifier and a heater and associated control system that controls the humidity and temperature in the neonatal microenvironment. The humidifier comprises a device that evaporates an evaporant, such as distilled water, to increase relative humidity of air within the neonatal microenvironment. The humidifier is typically controllable such that the amount of water, or water vapor, added to the microenvironment is adjustable in order to control the humidity to a desired value. The heater may be, for example, an air heater controllable to maintain the microenvironment area to a certain temperature. Radiant warmers may be used instead of incubators for some neonates where open patient access is useful. In still other embodiments, hybrid incubator/radiant warming systems may be utilized.

Since the microenvironment is accurately controlled in a neonatal care system, the care system includes an enclosure that is sealed as much as possible to help maintain the controlled microenvironment. Such an enclosure will typically include four sidewalls or side panels and a top hood that surround an infant support platform. Typically, one or more of the side panels can include access points, such as porthole doors, and a removable top, among others, that enable clinicians to access neonates in the microenvironment. In some examples, the access points may not be fully closed or sealed, which can alter the conditions of the microenvironment.

<CIT> is directed to a system that includes a base that supports a mattress and panels that extend upwardly from the base and together form an enclosure around the mattress. A porthole is defined through at least one of the panels, where the porthole provides access into the enclosure. A porthole door has locked and unlocked positions and covers the porthole only in the locked position. A detection system detects when the porthole door is in the unlocked position. A lighting system is operatively coupled to the detection system and is configured to emit light when the porthole door is detected to be in the unlocked position. A power system provides energy to the lighting system for emitting the light.

This Brief Description is provided to introduce a selection of concepts that are further described below in the Detailed Description.

An infant care station can include sensors to detect an environmental characteristic of the infant care station, an access point to access a microenvironment of the infant care station, and a processor to obtain a sealed measurement for the infant care station with the access point in a sealed position. The processor can also obtain the environmental characteristic from sensors monitoring the microenvironment of the infant care station. Additionally, the processor can determine a difference between the environmental characteristic and the sealed measurement and generate an alert indicating an access point sealing issue based on the difference exceeding a predetermined threshold. The access point sealing issue, as referred to herein, can indicate an unexpected open or unsealed access point, or an unexpected, sealed access point.

In some examples, the access point can include a canopy, a porthole door, equipment access point, or a combination thereof. In one aspect, the processor can transmit the alert to an external computing device or a remote display device. In some examples, the processor can display the alert in a user interface coupled to the system.

In one aspect, the environmental characteristic can include a pressure value, a humidity value, an oxygen value, a temperature control loop value, or a combination thereof. In some examples, the sensors can include a pressure sensor, an oxygen sensor, a humidity sensor, or a combination thereof.

In one aspect, the sensors are coupled to an enclosure of the system, wherein the enclosure supports the microenvironment. In some examples, the alert can include an audio feedback, haptic feedback, or visual feedback representing a message that the at least one access point is unsealed. In some examples, the infant care station can include an ambient sensor, wherein the ambient sensor can detect an ambient measurement, and wherein the processor can generate a second alert in response to detecting a difference between the ambient measurement and the environmental characteristic that exceeds an ambient threshold. In some examples, the sensors can include a pressure sensor within the microenvironment and the environmental characteristic can include a pressure value obtained from the microenvironment by the pressure sensor.

In some examples, a method can include obtaining an ambient air measurement from one or more ambient air sensors for an environment proximate to an infant care station. The method can also include obtaining an environmental characteristic from one or more microenvironment sensors and determining a difference between the environmental characteristic and the ambient measurement exceeds a predetermined threshold. Additionally, the method can include generating an alert indicating an access point sealing issue in the infant care station based on the difference exceeding the predetermined threshold. In one aspect, the method can include preventing the alert from being generated in response to detecting a user in proximity sensor data within a predetermined distance from the infant care station.

In one aspect, a non-transitory machine-readable medium for detecting an access point sealing issue in an infant care station can include a plurality of instructions that cause a processor to obtain a sealed measurement for the infant care station with the at least one access point in a sealed position, wherein the at least one access point comprises a canopy, a porthole door, an equipment access point, or a combination thereof. The plurality of instructions can also cause the processor to obtain an environmental characteristic from the one or more sensors and determine a difference between the environmental characteristic and the sealed measurement exceeds a predetermined threshold. In some examples, the plurality of instructions can also cause the processor to generate an alert indicating an access point sealing issue in the infant care station based on the difference exceeding the predetermined threshold.

In some examples, an infant care station can include a lighting system, at least one access point, and a processor that can detect, via one or more sensors, that the at least one access point is open. The processor can also provide, using the lighting system, a first color light in response to the detecting that the at least one access point is open, and provide the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point being open.

In one aspect, a method for illuminating an infant care station can include detecting that at least one access point is open using a sensor in the infant care station, providing, using a lighting system, a first color light in response to the detecting that the at least one access point is open, and providing the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point being open.

In another aspect, a non-transitory machine-executable media can include a plurality of instructions that in response to execution by a processor, cause the processor to detect, via one or more sensors, that the at least one access point is open. The plurality of instructions can also cause the processor to provide, using the lighting system, a first color light in response to the detecting that the at least one access point is open and provide the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point being open. In some examples, the plurality of instructions can cause the processor to obtain lighting system data representing the first color, the second color, and a time that the access point is open and transmit the lighting system data to a remote device.

The drawings illustrate the best mode presently contemplated of carrying out the disclosure. In the drawings:.

The drawings illustrate specific aspects of the described components, systems and methods for providing a neonatal incubator system. Together with the following description, the drawings demonstrate and explain the principles of the structures, methods, and principles described herein. In the drawings, the thickness and size of components may be exaggerated or otherwise modified for clarity. Well-known structures, materials, or operations are not shown or described in detail to avoid obscuring aspects of the described components, systems and methods.

Embodiments of the present disclosure will now be described, by way of example, with reference to <FIG>. Infant care stations can provide microenvironments for infant patients receiving medical care. Infant care stations, as referred to herein, can include incubators, warmers, or devices that support one or more features of incubators and warmers. In some examples, the infant care stations can enable clinicians to access the patient by opening one or more access points. An access point, as referred to herein, includes porthole doors that reside within one or more walls of the infant care stations, removable canopies of infant care stations, equipment access points, and the like. For example, a clinician may disengage any suitable latch coupled to the porthole doors to open the porthole doors and access a patient residing within an infant care station. However, porthole doors can be accidentally left open, which can result in unexpected conditions within the microenvironment of the infant care station. Also, radiant heaters of an infant care station can be improperly engaged when an infant care station transitions from a warmer with an open top or canopy to an incubator with a closed canopy. When the radiant heater remains engaged for an extended period of time with the canopy of the infant care station in a closed position, unexpected conditions can arise in the microenvironment.

Techniques described herein enable an infant care station to detect when an access point is sealed or unsealed. In some examples, an infant care station can include one or more sensors (also referred to herein as microenvironment sensors) that can measure, obtain, or otherwise detect an environmental characteristic of the microenvironment. The environmental characteristic, as referred to herein, can include a pressure level, an oxygen level, a humidity level, or a combination thereof obtained from the microenvironment of the infant care station. In some examples, the infant care station can monitor the environmental characteristic and determine when an access point is left unsealed or open based on a previously obtained sealed measurement from the microenvironment of the infant care station. The sealed measurement, as referred to herein, can indicate an expected pressure, oxygen level, humidity level, and the like, within the microenvironment when the porthole doors are in a sealed or closed position. Alternatively, the infant care station can detect an ambient characteristic or measurement, such as a pressure, oxygen level, or humidity level, from the surrounding environment outside of the infant care station. In some examples, the infant care station can compare the ambient characteristic to the environmental characteristic to determine if an access point is sealed or unsealed. In some examples, a sealed or unsealed access point refers to a gap between an access point and an infant care station exceeding a predetermined threshold. For example, a sealed access point can refer to a canopy or a porthole door, among other access points, that is positioned proximate walls of an infant care station such that a gap exists between the walls and the canopy or porthole door. In some examples, a gap that is smaller than a predetermined threshold represents a sealed access point and a gap greater than a predetermined threshold represents an unsealed access point.

An advantage that may be realized by the sealed access point illumination feature in the practice of some examples of the described systems and techniques is an additional safety mechanism to prevent an access point from remaining disengaged in an unsealed or open position for an extended period of time. The techniques herein can also prevent unexpected conditions within the microenvironment by detecting when an infant care station has transitioned from a warmer to an incubator and determining if a heater has turned off following the transition. Accordingly, techniques herein can prevent an unexpected alteration of the temperature, humidity, oxygen level, and the like, within the microenvironment of an infant care station. Techniques for illuminating sealed or unsealed access points are described in greater detail below in relation to <FIG>.

<FIG> is a perspective view of an example infant care station in accordance with one example. In the example of <FIG>, an infant care station is depicted in which the infant care station is an incubator <NUM>. The incubator <NUM> includes a horizontal surface <NUM> that is configured to support an infant patient (not depicted). It is to be understood that the incubator <NUM> may have the ability or control to move, rotate, or incline the horizontal surface <NUM>; however, it will be understood that the horizontal surface <NUM> will generally remain horizontal such as to minimize movement of the infant patient within the incubator <NUM> due to gravity.

One or more walls <NUM> extend generally vertically from the horizontal surface <NUM>. In the embodiment depicted in <FIG> of the incubator <NUM>, four walls extend vertically from the horizontal surface <NUM> to define the rectangular shape of the incubator <NUM>. However, it will be understood that in alternative examples, various numbers of walls <NUM> may be used to define the incubator into various geometric shapes which may include, but are not limited to, circles or hexagons. The incubator <NUM> can further include a canopy <NUM> that extends over the horizontal surface <NUM>. In some examples, the canopy <NUM> can include multiple components or surfaces, or the canopy may be curved or domed in shape.

While the incubator of <FIG> is depicted with the horizontal surface <NUM>, walls <NUM>, and canopy <NUM> being connected, it will be understood that in alternative examples, including those described in greater detail herein, the horizontal surface <NUM>, walls <NUM>, and canopy <NUM> may be individual components that also may be moveable with respect to each other. For example, the canopy <NUM> can transition from a closed position to an open position in which any suitable portion of the canopy <NUM> is raised away from the walls <NUM> to allow the microenvironment to be exposed to the surrounding environment of the incubator <NUM>.

The horizontal surface <NUM>, walls <NUM>, and canopy <NUM> can define a microenvironment <NUM> contained within these structures. In some examples, the incubator <NUM> is configured such that the microenvironment <NUM> surrounds the infant patient (not depicted) such that the infant patient is only exposed to a controlled combination of environmental characteristics or conditions (temperature, humidity, O<NUM> concentration, etc.) selected by a clinician to promote the health and wellbeing of the infant patient. In some examples, the walls <NUM> further include portholes <NUM> that permit a clinician access into the microenvironment <NUM>. The walls <NUM> can also include any number of equipment access points <NUM>. The equipment access points <NUM> can include grommet seals (or any other suitable seals) for cables, harnesses, and other medical equipment access holes. In some examples, seals and other equipment can fall out from the equipment access points <NUM> or the seals and other equipment can be damaged when equipment hoses or cables are removed.

In some examples, the incubator <NUM> includes a base <NUM> that houses a convective heater <NUM>. The convective heater <NUM> is operated such that air is drawn into the incubator <NUM>, at which point the air may be filtered or sterilized in another manner, including the use of UV light before being passed by heating coils (not depicted) to heat the air to a target or set point temperature. The sterilized and heated air is blown into the microenvironment <NUM> through vents (not depicted) which are arranged along the walls <NUM>. As is also known, the air may be entrained with supplemental gasses such as oxygen or may have added humidity such as to control these conditions within the microenvironment <NUM>.

Examples of the incubator <NUM> further include a pedestal <NUM> connected to the base <NUM>. The pedestal <NUM> includes mechanical components (not depicted), which may include, but are not limited to, servo motors, rack and pinion systems, or screw gear mechanisms that are operable by foot pedals <NUM> to raise or lower the base <NUM>, effectively raising or lowering the position of the infant patient (not depicted) in relation to the clinician. The incubator <NUM> may be moveable by wheels or casters <NUM> connected to the pedestal <NUM>.

The example of the incubator <NUM> depicted in <FIG> includes a graphical display <NUM> that is mounted to a wall, the base <NUM>, or the canopy <NUM> of the incubator <NUM> at a position external to the microenvironment <NUM>. The graphical display <NUM> is operated by a processor to present a graphical user interface (GUI) <NUM>. In the example illustrated, the graphical display <NUM> is a touch-sensitive graphical display and the GUI <NUM> is configured to specifically respond to inputs made by a clinician received through the touch-sensitive graphical display. During normal operation, the touch-sensitive graphical display <NUM> and touch-sensitive configured GUI <NUM> are used to control various functions of the incubator <NUM>. The GUI <NUM> presents a variety of information, such as the air temperature and alarm indications. In some examples, the alarm indications can provide a message indicating an access point is unsealed or open, a change in environment characteristics, or a warning that a heater is still operational after the canopy <NUM> has been closed, among others.

In some examples, the walls <NUM> of the incubator <NUM> can be opened or closed to enable a clinician to access a patient residing in the incubator <NUM>. For example, the walls <NUM> can serve as doors that open and close to either remove a patient from the incubator <NUM> or to place a patient into the incubator <NUM>. As described in greater detail below in relation to <FIG>, the walls <NUM> can include any number of access points, such as portholes <NUM> covered by porthole doors, that enable access to a patient residing in a microenvironment of the incubator <NUM>.

In some examples, the incubator <NUM> can include any number of sensors as part of a sensor system <NUM>. The sensor system <NUM> can include pressure sensors, oxygen sensors, humidity sensors, and the like. In some examples, the sensor system <NUM> is connected to a host device <NUM> that controls the GUI <NUM>. The sensor system <NUM> can transmit sensor data to the host device <NUM> and the host device <NUM> can determine if any access points, such as the canopy <NUM> or portholes <NUM>, of the incubator <NUM> are unsealed or open. In some examples, the sensor system <NUM> can transmit sensor data indicating environmental characteristics of a microenvironment to a host device <NUM> using any suitable wired or wireless transmission protocol. The host device <NUM> can determine if the access points are unsealed or open based on generating a difference using the sensor data in real-time and sealed measurements previously obtained from the incubator <NUM> or an ambient sensor measurement as discussed in greater detail below in relation to <FIG>.

is a block diagram of an example of a pressure sensor system within an infant care station. In some examples, the pressure sensor <NUM> of an infant care station is used to determine an environmental characteristic of a microenvironment of an infant care station. The pressure sensor <NUM> can be coupled to an analog-to-digital converter <NUM>, or the pressure sensor <NUM> and the analog-to-digital converter <NUM> can be combined to form an integrated pressure sensor <NUM>. The analog-to-digital converter <NUM> or the integrated pressure sensor <NUM> can transmit sensor data to a processor <NUM> at any suitable time interval such as one second, <NUM> seconds, one minute, or the like. The processor <NUM> can transmit the sensor data to a host device <NUM>, or the host device <NUM> of <FIG>, among others. In some examples, either the processor <NUM> or the host device <NUM> can determine if an access point is open or unsealed by determining if a measurement from the microenvironment of an infant care station exceeds a predetermined difference with an ambient sensor value or a sealed measurement previously obtained within the infant care station. In some examples, the processor <NUM> can transmit sensor data or data calculated based on the sensor data to the host device <NUM> using any suitable wired or wireless protocol.

In some examples, an infant care station, such as the incubator <NUM> of <FIG>, can include any number of pressure sensors <NUM>, among other sensors. The host device <NUM> can obtain sensor data from the pressure sensors <NUM> and any other sensors and determine if an infant care station has one or more access points that are either in an open or closed position. Additionally, in some examples, the analog-to-digital converter <NUM> or the integrated pressure sensor <NUM> can include logic to pre-process the sensor data to detect incorrect sensor data and the like.

<FIG> depicts a block diagram of an example system for detecting an access point sealing issue in an infant care station. In some examples, the infant care station <NUM> can include a frame <NUM> that supports a bed <NUM> within a patient cabin <NUM>. The patient cabin <NUM> can include four or more walls and a canopy, among other components that enable a microenvironment to form within the patient cabin <NUM>. For example, the patient cabin <NUM> can maintain a constant humidity, oxygen level, temperature, and the like for a patient residing on the bed <NUM>. In some examples, a pressure sensor system <NUM> is coupled to the patient cabin such that the pressure sensor system <NUM> can determine a pressure of the microenvironment.

In some examples, the pressure sensor system <NUM> can periodically or continuously transmit pressure sensor data to a host device <NUM>. The host device <NUM> can also obtain ambient sensor data or ambient measurements from ambient pressure sensors or an ambient pressure system <NUM> proximate to the host device <NUM>. The ambient pressure system <NUM> can provide the pressure values from the environment outside of the microenvironment. In some examples, the pressure values obtained, detected, or otherwise received from the ambient pressure system <NUM> can indicate an altitude of an infant care station <NUM>. For example, a lower pressure level can indicate that the infant care station <NUM> resides at a higher altitude.

In some examples, the host device <NUM> can obtain an environmental characteristic, such as a pressure of the microenvironment, from the pressure sensor system <NUM> and determine whether a difference between the environmental characteristic and the ambient measurement exceeds a predetermined threshold. If the difference does not exceed the predetermined threshold, the host device <NUM> may continue to monitor the microenvironment without generating an alert. If the difference does exceed the predetermined threshold, the host device <NUM> can generate an alert indicating an unsealed access point in the infant care station based on the difference exceeding the predetermined threshold.

In some examples, the alert can be provided to a user with the visual display <NUM>, using haptic feedback, or audio feedback, among others. In some examples, the visual display <NUM> can be coupled to the host device <NUM> or the visual display <NUM> can reside in a remote location. The alert can include a message that the at least one access point is unsealed or that a canopy of an infant care station <NUM> has transitioned to a closed position from an open position.

In some examples, the host device <NUM> can obtain environmental characteristics from any number of sensors coupled to the infant care station <NUM>. The sensors can monitor the oxygen level, humidity level, and the like, from within the microenvironment, or the sensors can monitor components that control the temperature of the microenvironment. For example, the host device <NUM> can detect a decrease in oxygen level of a microenvironment of an infant care station <NUM>, which indicates an open access point, such as a porthole door or a canopy. The host device <NUM> can also detect an increase or decrease in power consumption by a convective heater, convective heater fan, among other heater components, of an infant care station <NUM>.

It is to be understood that the block diagram of <FIG> is not intended to indicate that the infant care station <NUM> is to include all of the components shown in <FIG>. Rather, the infant care station <NUM> can include fewer or additional components not illustrated in <FIG> (e.g., additional memory components, embedded controllers, additional modules, additional network interfaces, additional sensor devices, etc.).

<FIG> depicts a process flow diagram of an example method for detecting an access point sealing issue in an infant care station. The method <NUM> can be implemented with any suitable infant care station, such as the incubator <NUM> of <FIG> or the infant care station <NUM> of <FIG>, among others.

At block <NUM>, the method <NUM> can include obtaining, detecting, or otherwise receiving a sealed measurement for an infant care station with at least one access point in a sealed position or obtaining, detecting, or otherwise receiving an ambient measurement. In some examples, the sealed measurement can be obtained as a predetermined value detected using one or more sensors of an infant care station when the access points are sealed or closed. The sensors can detect any suitable sealed measurement such as a pressure level within the microenvironment of the infant care station, a humidity level within the microenvironment of the infant care station, an oxygen level within the microenvironment of the infant care station, a temperature control loop value, or any combination thereof. The temperature control loop value can indicate any suitable measurement used to control a fan motor, a heater duty cycle, a radiant heater fan speed, or the like. The temperature control loop value can be obtained with any suitable control loop sensor that monitors the power consumption of heating components within an infant care station. In some examples, the temperature control loop value can indicate a fan speed, heater elements on or off times, an increased wattage for a radiant heater, and an increased wattage for a humidifier heater, among others. The temperature control loop value can represent when a heater of an infant care station is providing heat to a microenvironment. In some examples, the temperature control loop value is modified in response to detecting a temperature variation in the microenvironment. For example, an increase or a decrease of a temperature of the microenvironment can cause a heater of an infant care station to provide a modified amount of heat so that the temperature of the microenvironment is maintained within a predetermined temperature range.

In some examples, the method <NUM> can detect, determine, or otherwise obtain an ambient measurement instead of, or in addition to, obtaining a sealed measurement. The ambient measurement can be measured or obtained by an ambient sensor monitoring the environment proximate an infant care station as described in greater detail above in relation to <FIG>. The ambient measurement can indicate a pressure level or humidity level, among others, of the environment surrounding an infant care station.

At block <NUM>, the method <NUM> can include obtaining the environmental characteristic from one or more microenvironment sensors monitoring the microenvironment. The microenvironment sensors can include pressure sensors, humidity sensors, oxygen sensors, and the like. In some examples, the microenvironment sensors can be placed at any suitable location within the enclosure or cabin of an infant care station to monitor environmental characteristics such as pressure levels, oxygen levels, and humidity levels, among others. For example, pressure sensors, oxygen sensor, humidity sensors, and the like, can be placed proximate to porthole doors or canopies, among other access points. In some examples, one or more pressure sensors can be included within an infant care station to detect a set of pressure values from different locations within the microenvironment. The set of pressure values can enable a host device to determine an average pressure value or a difference in pressure values. The difference in pressure values can be used to calculate or compute a rate of change in the pressure values detected by each of the pressure sensors, which can indicate the pressure sensor that is closest to an unsealed or open access point. In some examples, multiple pressure sensors, oxygen sensors, humidity sensors, or other microenvironment sensors, can be used to determine an open or unsealed access point by detecting the microenvironment sensor that is monitoring the faster rate of change as compared to other microenvironment sensors in the infant care station.

The method <NUM> can also include obtaining sensor data values from different types of sensors monitoring the microenvironment of an infant care station. In some examples, the sensors can obtain sensor data directly from the microenvironment or indirectly by monitoring the operation of heaters and other components of the infant care station. For example, the sensors can indirectly determine a temperature change or temperature stability of the microenvironment of an infant care station by monitoring sensor data from control loop sensors that detect, determine, or otherwise obtain the temperature control loop values that represent the operation of radiant heaters, among other components, of the infant care station. In some examples, the sensors can detect sensor data indicating that a control loop for an infant care station is becoming more active, which can represent a perturbation of the microenvironment of the infant care station via the increased control loop activity.

At block <NUM>, the method <NUM> can include determining a difference between the environmental characteristic and either the sealed measurement or the ambient measurement. As discussed above in relation to block <NUM>, the sealed measurement can be obtained from the microenvironment of the infant care station with the access points in a sealed or closed position and the ambient measurement can be obtained from any suitable ambient sensor. The difference between either the environment characteristic and the sealed measurement or the environmental characteristic and the ambient measurement can represent a step change in pressure, oxygen level, humidity, and the like, within the microenvironment of an infant care station. The difference can indicate that one or more access points may have been unsealed or opened for a period of time. For example, the difference can indicate that a porthole door, a canopy, or any other suitable access point of an infant care station has been opened. In some examples, an open access point can enable warm air from the microenvironment to exit the infant care station into the surrounding environment. The difference can also indicate that the infant care station has transitioned from an open canopy position to a closed canopy position.

In some examples, the sensors can also include global positioning system (GPS) coordinates that map the location of the infant care station to a known altitude. The known altitude can be used when determining if the environmental characteristic exceeds a predetermined threshold. For example, the altitude can be used to determine an expected pressure of the environment surrounding the infant care station, an expected baseline pressure of the microenvironment in an unsealed or open position, or the like.

At block <NUM>, the method <NUM> can include generating an alert indicating an access point sealing issue based on the difference exceeding a predetermined threshold. The access point sealing issue, as referred to herein, can indicate an unexpected open or unsealed access point or an unexpected, sealed access point. For example, the access point sealing issue can indicate an open porthole door or a closed canopy, among others. In some examples, the alert can indicate an amount of time any number of access points have been open, whether the amount of time an access point has been open exceeds a predetermined threshold, a pressure value, an oxygen value, a humidity value, a rate of change in a set of pressure values, oxygen values, or humidity values, or a delta value representing a change in pressure values, oxygen values, or humidity values within a predetermined period of time, among others. In some examples, the alert can indicate values from two or more different types of sensors have exceeded predetermined thresholds. For example, the alert can indicate a difference between a measured pressure value and a predetermined sealed pressure value for the infant care station has exceeded a first threshold and a difference between a measured oxygen level and a predetermined sealed oxygen level for the infant care station has exceeded a second threshold. In some examples, any number of types of sensors can detect different sensor values and the alert can indicate if any of the different sensors obtain sensor values that exceed one or more thresholds. For example, the sensor devices can include sensors that monitor the pressure, humidity, and oxygen level of the microenvironment in addition to any number of sensors that monitor the temperature control loop values for an infant care station.

In some examples, the alert can be based on the difference between the environmental characteristic and the sealed measurement combined with a difference between the environmental characteristic and an ambient measurement. The ambient measurement can be obtained from an ambient sensor located outside of the microenvironment as described in greater detail above in relation to <FIG>. In some examples, the unsealed pressure of a microenvironment of an infant care station can be lower than the sealed pressure of the infant care station, and yet can be higher than the ambient pressure level around the infant care station. The method <NUM> can include, in some examples, determining if one or more access points are unsealed based on whether the pressure of a microenvironment is closer to a sealed measurement or an ambient measurement.

Still at block <NUM>, in some examples, the alert can indicate a particular access point that is experiencing an access point sealing issue. For example, the method <NUM> can include determining the rate of change of pressure within a microenvironment. A slower rate of change can indicate one or more porthole doors that are unsealed. A faster rate of change of the pressure level can indicate an open or closed canopy in an infant care station. In some examples, the method <NUM> can include obtaining predetermined rates of change in pressure, or any other suitable environmental characteristic, corresponding to one or two unsealed porthole doors, an unsealed canopy, or any other access points. The method <NUM> can include generating an alert that indicates the specific access points that are likely unsealed based on the predetermined rates of change in pressure or changes in other environmental characteristics. For example, the method <NUM> can include determining if one porthole door is unsealed with a sealed canopy, two porthole doors are unsealed with a sealed canopy, two porthole doors are sealed with an unsealed canopy, or any combination thereof.

In some examples, the alert can also include the sensor data detected from one or more microenvironment sensors such that the alert can indicate the pressure sensor values, humidity values, oxygen level values, temperature control loop values, and the like. The sensor data from the alert can be displayed by a display device coupled to an infant care station or a remote device that received the alert from the infant care station.

The process flow diagram of method <NUM> of <FIG> is not intended to indicate that all of the operations of blocks <NUM>-<NUM> of the method <NUM> are to be included in every example. Additionally, the process flow diagram of method <NUM> of <FIG> describes a possible order of executing operations. However, it is to be understood that the operations of the method <NUM> can be implemented in various orders or sequences. In addition, in some examples, the method <NUM> can also include fewer or additional operations. For example, the method <NUM> can include determining when a canopy of an infant care station is transitioned from an open position to a closed position. In the open position, the canopy does not contact all four side walls so that the microenvironment is exposed to the surrounding environment. In the closed position, the canopy contacts all four side walls of the infant care station to seal the microenvironment from the surrounding environment. When the canopy is in a closed position, a radiant heater can be turned off. In some examples, the method <NUM> can determine that the canopy is in a closed position by monitoring the environmental characteristic to determine an increase in a pressure value of the microenvironment, a temperature control loop value indicating that the heater is still in operation, or the like. The method <NUM> can generate an alert in response to detecting the heater of the infant care station is still operating with the canopy in a closed position. For example, the method <NUM> can include generating an alert when a pressure value from a microenvironment falls below a predetermined threshold and turning off the power to a heater of the infant care station.

Additionally, in some examples, the method <NUM> can include detecting a rate of change of an environmental characteristic and determining that the rate of change is below a predetermined threshold, which can indicate an issue with one or more equipment access points. For example, a gradual loss of pressure below a threshold value can indicate a damaged seal around one or more hoses, cables, and the like, that are placed through access point holes in the walls of an infant care station. In some examples, the method <NUM> can include generating an alert that indicates a damaged equipment access point in response to detecting a change in an environmental characteristic that is below a predetermined threshold.

<FIG> is a block diagram of an example of a computing device that can detect an access point sealing issue of an infant care station. The computing device <NUM> may be, for example, an infant care station device, such as an incubator, a warmer, or a device that provides features of both an incubator and a warmer, a laptop computer, a desktop computer, a tablet computer, or a mobile phone, among others. The computing device <NUM> may include a processor <NUM> that is adapted to execute stored instructions, as well as a memory device <NUM> that stores instructions that are executable by the processor <NUM>. The processor <NUM> can be a single core processor, a multi-core processor, a computing cluster, or any number of other configurations. The memory device <NUM> can include random access memory, read only memory, flash memory, or any other suitable memory systems. The instructions that are executed by the processor <NUM> may be used to implement a method that can detect an open or unsealed access point of an infant care station, as described in greater detail above in relation to <FIG>.

The processor <NUM> may also be linked through the system interconnect <NUM> (e.g., PCI, PCI-Express, NuBus, etc.) to a display interface <NUM> adapted to connect the computing device <NUM> to a display device <NUM>. The display device <NUM> may include a display screen that is a built-in component of the computing device <NUM>. The display device <NUM> may also include a computer monitor, television, or projector, among others, that is externally connected to the computing device <NUM>. The display device <NUM> can include light emitting diodes (LEDs), and micro-LEDs, among others.

The processor <NUM> may be connected through a system interconnect <NUM> to an input/output (I/O) device interface <NUM> adapted to connect the computing device <NUM> to one or more I/O devices <NUM>. The I/O devices <NUM> may include, for example, a keyboard and a pointing device, wherein the pointing device may include a touchpad or a touchscreen, among others. The I/O devices <NUM> may be built-in components of the computing device <NUM>, or may be devices that are externally connected to the computing device <NUM>.

In some embodiments, the processor <NUM> may also be linked through the system interconnect <NUM> to a storage device <NUM> that can include a hard drive, an optical drive, a USB flash drive, an array of drives, or any combinations thereof. In some embodiments, the storage device <NUM> can include any suitable applications. In some embodiments, the storage device <NUM> can include an access point manager <NUM>. In some embodiments, the access point manager <NUM> can obtain a sealed measurement for an infant care station with at least one access point in a sealed position, obtain the environmental characteristic from one or more sensors, and determine a difference between the environmental characteristic and the sealed measurement. The access point manager <NUM> can also generate an alert indicating an access point sealing issue based on the difference. In some examples, the alert can also indicate that maintenance is to be scheduled for the access point and provide the alert using any suitable user interface or display device. For example, the alert can indicate that a latch or a gasket of a porthole may be malfunctioning, which prevents a porthole door from sealing. The alert can also indicate that a heater is not turning off when an infant care station transitions from a warmer with an open canopy to an incubator with a closed canopy. In some examples, the access point manager <NUM> can be stored in storage <NUM> or within memory device <NUM> accessible by the processor <NUM>, among others.

The access point manager <NUM> can also obtain an ambient measurement from one or more ambient sensors for an environment proximate to an infant care station, obtain an environmental characteristic from one or more microenvironment sensors proximate to at least one access point of the infant care station, determine a difference between the environmental characteristic and the ambient measurement exceeds a predetermined threshold, and generate an alert indicating an access point sealing issue in the infant care station based on the difference exceeding the predetermined threshold. In some examples, the alert can be based on the difference between the environmental characteristic and the ambient measurement, based on the difference between the environment characteristic and a sealed measurement, or a combination thereof. In some examples, the access point manager <NUM> can generate a first alert in response to detecting a difference between a sealed measurement and an environmental characteristic. The access point manager <NUM> can also generate a second alert in response to detecting a difference between the ambient measurement and the environmental characteristic that exceeds an ambient threshold. The ambient threshold can indicate a maximum difference between the ambient measurement and the environmental characteristic before an alert is generated.

In some examples, the display device <NUM> can provide a user interface that indicates data from the alert such as sensor data from the microenvironment sensors, and the like. The display device <NUM> can also provide a visual representation of an infant care station, wherein the visual representation indicates which of the access points of the infant care station are in an unexpected sealed or unsealed position. For example, the display device <NUM> can provide a visual representation indicating an open porthole door, a closed canopy with a heater still generating heat for the microenvironment, or the like.

In some examples, the access point manager <NUM> can obtain proximity sensor data from one or more cameras, proximity sensors, and the like. The access point manager <NUM> can prevent generating or providing an alert if a user is detected in the proximity sensor data within a predetermined distance from an infant care station. For example, the access point manager <NUM> can obtain, detect, or otherwise receive proximity sensor data that indicates the presence of a user near an infant care station. In some examples, if the access point manager <NUM> detects an unsealed or open access point while a user is proximate to the infant care station, the access point manager <NUM> can prevent displaying or otherwise providing an alert. In some examples, the access point manager <NUM> can delay providing an alert for a predetermined period of time or delay providing an alert until a user is no longer in proximate to the infant care station.

In some examples, a network interface controller (also referred to herein as a NIC) <NUM> may be adapted to connect the computing device <NUM> through the system interconnect <NUM> to a network <NUM>. The network <NUM> may be a cellular network, a radio network, a wide area network (WAN), a local area network (LAN), or the Internet, among others. The network <NUM> can enable data, such as alerts, among other data, to be transmitted from the computing device <NUM> to remote computing devices, remote display devices, remote user interfaces, and the like.

It is to be understood that the block diagram of <FIG> is not intended to indicate that the computing device <NUM> is to include all of the components shown in <FIG>. Rather, the computing device <NUM> can include fewer or additional components not illustrated in <FIG> (e.g., additional memory components, embedded controllers, additional modules, additional network interfaces, etc.). Furthermore, any of the functionalities of the access point manager <NUM> may be partially, or entirely, implemented in hardware and/or in the processor <NUM>. For example, the functionality may be implemented with an application specific integrated circuit, logic implemented in an embedded controller, or in logic implemented in the processor <NUM>, among others. In some embodiments, the functionalities of the access point manager <NUM> can be implemented with logic, wherein the logic, as referred to herein, can include any suitable hardware (e.g., a processor, among others), software (e.g., an application, among others), firmware, or any suitable combination of hardware, software, and firmware.

<FIG> depicts a non-transitory machine-executable medium with instructions that can detect an access point sealing issue in an infant care station. The non-transitory, machine-readable medium <NUM> can cause a processor <NUM> to implement the functionalities of method <NUM>. For example, a processor of an infant care station, a host device, a computing device (such as processor(s) <NUM> of computing device <NUM> of <FIG>), or any other suitable device, can access the non-transitory, machine-readable media <NUM>.

In some examples, the non-transitory, machine-readable medium <NUM> can include instructions to execute an access point manager <NUM>. For example, the non-transitory, machine-readable medium <NUM> can include instructions that cause the processor <NUM> to obtain a sealed measurement for an infant care station with at least one access point in a sealed position, obtain the environmental characteristic from one or more sensors, and determine a difference between the environmental characteristic and the sealed measurement. The non-transitory, machine-readable medium <NUM> can also include instructions that cause the processor <NUM> generate an alert indicating an access point sealing issue based on the difference. In some examples, the non-transitory, machine-readable medium <NUM> can include instructions to implement any combination of the techniques of the method <NUM> described above.

For example, the machine-readable medium <NUM> can also include instructions to obtain an ambient measurement from one or more ambient sensors for an environment proximate to an infant care station, obtain an environmental characteristic from one or more microenvironment sensors proximate to at least one access point of the infant care station, determine a difference between the environmental characteristic and the ambient measurement exceeds a predetermined threshold, and generate an alert indicating an access point sealing issue in the infant care station based on the difference exceeding the predetermined threshold.

<FIG> depicts a process flow diagram of an example method for providing an open access point indicator in an infant care station. The method <NUM> can be implemented with any suitable infant care station, such as the incubator <NUM> of <FIG>, the infant care station <NUM> of <FIG>, the infant care station <NUM> of <FIG>, the infant care station 900A of <FIG>, the infant care station 900B of <FIG>, the infant care station <NUM> of <FIG>, or the computing device <NUM> of <FIG>, among others.

At block <NUM>, the method can include detecting that at least one access point is open. In some examples, the method can include detecting a change in an environmental characteristic from a microenvironment of the infant care station. The environmental characteristic can include a temperature of the microenvironment, a humidity level of the microenvironment, or an oxygen level of the microenvironment. In some examples, as described above in relation to <FIG>, the environmental characteristic can be obtained, received, or otherwise determined based on sensor data from sensors monitoring the microenvironment of the infant care station. The sensors can be placed proximate or adjacent to one or more access points of an infant care station or at any other suitable location in the infant care station.

In some examples, the method can include detecting an open access point based on a change in environmental characteristics between an ambient air sensor value obtained from outside the infant care station and a sensor value obtained within the microenvironment of the infant care station. The method can also include detecting an open access point based on a difference or a change in environmental characteristics between an initial sensor value and a real-time sensor value. For example, the initial sensor value can indicate environmental characteristics when access points of an infant care station are in a closed position and a comparison of real-time values to the initial sensor value can indicate if an access point is open in the infant care station.

At block <NUM>, the method can include providing, using the lighting system, a first color light in response to the detecting that the at least one access point is open. The first color light can be an indicator that an access point is open or unsealed for an amount of time that exceeds a predetermined threshold. In some examples, the lighting system is proximate or adjacent to the at least one access point that is open. The lighting system can include one or more lights, a light bar, or the like. In some examples, the first color light can indicate an open access point or any other suitable environmental characteristics for the infant care station. For example, the first color light can indicate whether a humidity level, temperature, oxygen level, or the like, has exceeded a set of high and/or low threshold values.

At block <NUM>, the method can include providing the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point being open. For example, the method can include modifying or adjusting the brightness, hue, lightness, chroma, colorfulness, or saturation, among others, of the first color light as an indicator for an environmental characteristic that changes over time or as an amount of time that an environmental characteristic exceeds a threshold increases. For example, a first color light in a light system of an infant care station can be modified to provide a color with more brightness as the amount of time an access point is open increases or the amount of time an environmental characteristic of an infant care station exceeds a threshold value. In some examples, the lighting system can provide a first color light after an access point, such as a porthole door, canopy, or the like, is left in an open or unsealed position for <NUM> seconds, <NUM> seconds, <NUM> minute, <NUM> minutes, or any other suitable period of time. The lighting system can provide a second color light in response to the access point remaining in an open or unsealed position for <NUM> seconds, <NUM> minute, <NUM> minutes, or any other suitable period of time following the first color light being provided.

In some examples, the method can include providing a second color light with the same light that provides the first color of the lighting system or using a second light of the lighting system. For example, the color provided by a first light of the lighting system can transition or change to a second color after a predetermined period of time with an open access point. In some examples, the lighting system can include two or more lights and the second light can provide a color indicator after a period of time with an open access point. In some examples, the first color light and the second color light can be configured by a user to represent different environmental characteristics and/or an open access point. For example, the first color light and the second color light can be configurable such that any suitable color can indicate a particular environmental characteristic or an open access point.

At block <NUM>, the method can include providing a supplemental indicator that includes a third color, an audible alert, a modified illumination of the lighting system of the infant care station, or the like. The supplemental indicator, as referred to herein, can represent any additional information regarding the environmental characteristics of the microenvironment of an infant care station, information related to an open or unsealed access point, or the like. For example, the method can also include providing a third color with the lighting system. The third color can represent the change in the environmental characteristic, an open access point, or the like. For example, a first light, a second light, or a combination thereof can provide color indicators that an access point is open in an infant care station. The third color can simultaneously indicate a change in environmental characteristics of the infant care station. For example, the third color can indicate a change in a temperature, humidity level, oxygen level, or the like of the infant care station.

In some examples, the method can include changing a portion of the lighting system that is illuminated based on the predetermined period of time in which the at least one access point is open or unsealed. For example, a number of lights or the area of the lighting system can provide more illumination as the time that an access point is open increases. In some examples, the method can include providing an audible alarm after the lighting system has provided the second color for a second period of time. The audible alarm can be provided by the infant care station or a remote system electronically coupled to the infant care station using any suitable wired or wireless protocol.

Still at block <NUM>, in some examples, the lighting system can be located along an edge of a porthole door, and the method can include illuminating a first portion of the lighting system in response to the detecting that the at least one access point is open. The method can also include illuminating a second portion of the lighting system in response to the predetermined period of time elapsing with the at least one access point being open.

In some examples, the method can include obtaining lighting system data representing the first color, the second color, and a time that the access point is open, and transmitting the lighting system data to a remote device. For example, the lighting system data can be transmitted using any suitable wired or wireless protocol to a remote device. The remote device can display the lighting system data representing an amount of time each access point has been opened, the change in environmental characteristics, or the like.

In some examples, the method can include simultaneously providing two or more different color lights with the lighting system in response to detecting that at least one access point is open and detecting a reduction in a humidity level of a microenvironment of the infant care station or a reduction in a temperature of the microenvironment of the infant care station. For example, the method can include displaying a first color, such as red, blue, green, or the like, in response to detecting an open access point. The method can also include displaying a second color, third color, or any number of colors, wherein each color represents one or more environmental characteristics. For example, the second color can represent a change in a humidity level that exceeds a predetermined threshold, a third color can represent a change in a temperature that exceeds a predetermined threshold, a fourth color can represent a change in an oxygen level of the microenvironment that exceeds a predetermined threshold, and the like. In some examples, a second light or a third light, among others, can display a color that represents two or more environmental characteristics in a combined manner. For example, a particular color can be assigned to a combination of environmental characteristics to represent a change in humidity and a change in temperature that both exceed threshold values, a change in temperature and oxygen levels that both exceed threshold values, or any other suitable combination of environmental characteristics.

The process flow diagram of method <NUM> of <FIG> is not intended to indicate that all of the operations of blocks <NUM>-<NUM> of the method <NUM> are to be included in every example. Additionally, the process flow diagram of method <NUM> of <FIG> describes a possible order of executing operations. However, it is to be understood that the operations of the method <NUM> can be implemented in various orders or sequences. In addition, in some examples, the method <NUM> can also include fewer or additional operations. For example, the method can also include automatically initiating an air boost component in the infant care station in response to the detecting that at least one access point is open. The air boost component is described in greater detail below in relation to <FIG>. In some examples, the method <NUM> can include detecting an open access point when an infant care station is in an open state or a closed state, or when any number of access points are open. An open state, as referred to herein, can include an infant care station with at least one open access point. A closed state, as referred to herein, can include an infant care station with each of the access points in a closed or sealed position.

<FIG> is an example block diagram of an infant care station with a lighting system located adjacent to an access point. In some examples, the infant care station <NUM> can include the various components and features of the incubator <NUM> of <FIG>. Additionally, the infant care station <NUM> can include a lighting system, such as a light bar <NUM>. The one or more light bars <NUM> can be coupled to or integrated within an infant care station <NUM>. The light bars <NUM> can be curved along the perimeter of an access point, in a straight series of lights proximate or adjacent to the access point, or the like. In the example of <FIG>, the light bars <NUM> are curved along the perimeter of portholes <NUM> in the walls <NUM> of infant care station <NUM>.

The light bars <NUM> can provide any number of lights as time progresses with an environmental characteristic change driving an alert. For example, the light bars <NUM> can display a first light color or first light intensity for a portion of the light bars <NUM> in response to a change in environmental characteristics for an infant care station <NUM>. The light bars <NUM> can display a second light color or second light intensity for a larger portion of the light bars <NUM> as time progresses with the change in the environmental characteristic. For example, if the change in the environmental characteristic corresponds to a change in the temperature of the infant care station, the light bar <NUM> can progressively display more lights or illuminate a larger portion of the light bar <NUM> as time progresses without the temperature of the infant care station <NUM> returning to an expected state or an expected temperature.

In some examples, each access point of an infant care station <NUM> can have a light bar adjacent to the access points <NUM>, <NUM>, and <NUM>. Each light bar <NUM> can be individually triggered to provide an alert by a change in environmental characteristics proximate to the access point near the light bar <NUM>. Alternatively, the light bars <NUM> can be interconnected and the light bars <NUM> can display a shared alert proximate to any number of access points <NUM>, <NUM>, and <NUM> in response to a change in environmental characteristics.

<FIG> and <FIG> are example block diagrams of an infant care station with a lighting system located adjacent to an access point. In some examples, such as <FIG>, the lighting system can include a single light <NUM> that provides one or more colors. For example, the light <NUM> can provide a first color in response to detecting an open access point or a change in environmental characteristics of an infant care station 900A. The light <NUM> can provide a second color after a period of time in which the access point is still open, or the environmental characteristics are still outside of a threshold range. In some examples, as discussed above in relation to <FIG>, the light <NUM> can change brightness or any other setting to indicate that an access point remains open, or an alert is still available regarding environmental characteristics.

In <FIG>, the lighting system of infant care station 900B can include two lights <NUM> and <NUM>. The first light <NUM> can operate similarly to <FIG> by indicating an open access point <NUM>, <NUM>, or <NUM>, or a change in environmental characteristics of the infant care station 900B. In some examples, the second light <NUM> of the lighting system can provide a same color as the first light <NUM> or a second color in response to a period of time elapsing without the access point <NUM>, <NUM>, or <NUM> being closed or the environmental characteristics changing to be within a predetermined threshold range. The second light <NUM> can, in some examples, alternatively provide a representation of the environmental characteristics as the first light <NUM> provides a representation of the access point <NUM>, <NUM>, or <NUM> being open. For example, the first light <NUM> can provide a first color in response to detecting an open access point <NUM>, <NUM>, or <NUM> and the second light <NUM> can provide a second color in response to detecting one or more environmental characteristics that are outside of a predetermined range.

In some examples, the lighting system of <FIG> can include more than two lights. The lights <NUM> and <NUM> of infant care station 900B can also be included in any suitable arrangement or orientation. For example, the lights <NUM> and <NUM> can be included at the top, bottom, sides, or any other suitable location adjacent to access points <NUM>, <NUM>, or <NUM>, among others.

<FIG> is an example of an infant care station with an air boost component. In some examples, the infant care station can <NUM> include an air boost component <NUM> located along or proximate to one or more access points <NUM>, <NUM>, or <NUM>. The air boost component <NUM> can also be included under a mattress of an infant care station <NUM>, or at any other suitable location.

In some examples, the air boost component <NUM> can project or extrude high pressure air to prevent the microenvironment of the infant care station <NUM> from interacting with ambient air located outside of the infant care station <NUM>. For example, the air boost component <NUM> can include a fan or any other suitable component of an infant care station <NUM> that can increase the speed at which air is circulated along one or more walls and a canopy of an infant care station <NUM>. The air boost component <NUM> can include, in some examples, a speed control for one or more fans of an infant care station <NUM> that causes the one or more fans to increase speed in order to circulate more air within the microenvironment of the infant care station <NUM>. For example, the air boost component <NUM> can cause a fan of an infant care station <NUM> to rotate at a higher rate of revolutions per minute in response to detecting an open access point.

The air boost component <NUM> can be enabled in response to detecting an open access point <NUM>, <NUM>, or <NUM> in the infant care station <NUM>. For example, the infant care station <NUM> can detect an open access point <NUM>, <NUM>, or <NUM> and enable or engage the air boost component <NUM> to prevent a change in the environmental characteristics of the infant care station <NUM>. In some examples, the air boost component <NUM> can be enabled or engaged as a lighting system <NUM> is activated to indicate an open access point <NUM>, <NUM>, or <NUM>. The lighting system <NUM> can have one or more lights to indicate that the air boost component <NUM> has been activated. In addition, the infant care station <NUM> can have one or more display devices, such as graphical display <NUM>, that indicate when the air boost component <NUM> is engaged or activated.

<FIG> is an example computing device that can provide an open access point indicator for an infant care station. The computing device <NUM> may be, for example, an infant care station device, such as an incubator, a warmer, or a device that provides features of both an incubator and a warmer, a laptop computer, a desktop computer, a tablet computer, or a mobile phone, among others. The computing device <NUM> may include a processor <NUM> that is adapted to execute stored instructions, as well as a memory device <NUM> that stores instructions that are executable by the processor <NUM>. The processor <NUM> can be a single core processor, a multi-core processor, a computing cluster, or any number of other configurations. The memory device <NUM> can include random access memory, read only memory, flash memory, or any other suitable memory systems. The instructions that are executed by the processor <NUM> may be used to implement a method that can detect an open or unsealed access point of an infant care station and illuminate a lighting system of the infant care station, as described in greater detail above in relation to <FIG>.

The processor <NUM> can also be connected through a system interconnect <NUM> to a lighting system <NUM>. In some examples, the lighting system <NUM> can include any number of lights, such as light emitting diodes, among others. The lights of the lighting system <NUM> can be arranged in any suitable configuration, such as a rectangle, square, circle, or the like, along an edge of an infant care station. For example, the lighting system <NUM> can include lights that are arranged adjacent to or proximate to any number of access points such as porthole doors, canopies, and the like of an infant care station. In some examples, the lighting system <NUM> can also include any number of components to illuminate one or more lights. The components can include power adapters, analog-to-digital converters, and the like.

In some embodiments, the processor <NUM> may also be linked through the system interconnect <NUM> to a storage device <NUM> that can include a hard drive, an optical drive, a USB flash drive, an array of drives, or any combinations thereof. In some embodiments, the storage device <NUM> can include any suitable applications. In some embodiments, the storage device <NUM> can include an access point manager <NUM> and a light display manager <NUM>. In some embodiments, the access point manager <NUM> can detect that the at least one access point is open using any suitable technique, such as the method <NUM> of <FIG>, among others. The light display manager <NUM> can provide, using the lighting system <NUM>, a first color light in response to the detecting that the at least one access point is open. In some examples, the light display manager <NUM> can also provide the first color light with a modified brightness or provide a second color light with the lighting system <NUM> after a predetermined period of time elapses with at least one access point being open.

In some examples, the display device <NUM> can provide a user interface that indicates data from the alert such as sensor data from the microenvironment sensors, and the like. The display device <NUM> can also provide a visual representation of an infant care station, wherein the visual representation indicates which of the access points of the infant care station are in an unexpected sealed or unsealed position. For example, the display device <NUM> can provide a visual representation indicating an open porthole door, a closed canopy with a heater still generating heat for the microenvironment, or the like. The display device <NUM> can also provide a status of the lighting system <NUM> of the computing device <NUM>. For example, the display device <NUM> can indicate if one or more lights of the lighting system <NUM> are illuminated and provide information, such as lighting system data, that explains the status of the one or more lights. The lighting system data, as referred to herein, can include data representing a first color of a lighting system, a second color of a lighting system, or any other number of colors provided by a lighting system along with a time that one or more access points are open and one or more environmental characteristics that exceed a predetermined range.

It is to be understood that the block diagram of <FIG> is not intended to indicate that the computing device <NUM> is to include all of the components shown in <FIG>. Rather, the computing device <NUM> can include fewer or additional components not illustrated in <FIG> (e.g., additional memory components, embedded controllers, additional modules, additional network interfaces, etc.). Furthermore, any of the functionalities of the access point manager <NUM> may be partially, or entirely, implemented in hardware and/or in the processor <NUM>. For example, the functionality may be implemented with an application specific integrated circuit, logic implemented in an embedded controller, or in logic implemented in the processor <NUM>, among others. In some embodiments, the functionalities of the access point manager <NUM> and the light display manager <NUM> can be implemented with logic, wherein the logic, as referred to herein, can include any suitable hardware (e.g., a processor, among others), software (e.g., an application, among others), firmware, or any suitable combination of hardware, software, and firmware.

<FIG> depicts a non-transitory machine-readable medium with instructions that can provide open access point indicators for an infant care station. The non-transitory, machine-readable medium <NUM> can cause a processor <NUM> to implement the functionalities of method <NUM>. For example, a processor of an infant care station, a host device, a computing device (such as processor(s) <NUM> of computing device <NUM> of <FIG>), or any other suitable device, can access the non-transitory, machine-readable media <NUM>.

In some examples, the non-transitory, machine-readable medium <NUM> can include instructions to execute an access point manager <NUM> and a light display manager <NUM>. For example, the non-transitory, machine-readable medium <NUM> can include instructions that cause the processor <NUM> to detect an open access point. The non-transitory, machine-readable medium <NUM> can also include instructions that cause the processor <NUM> to provide, using the lighting system, a first color light in response to the detecting that the at least one access point is open and provide the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point being open. In some examples, the non-transitory, machine-readable medium <NUM> can include instructions to implement any combination of the techniques of the method <NUM> described above.

<FIG> is an example process flow diagram of a method for providing an indicator in response to detecting movement of a patient in an infant care station. The method <NUM> can be implemented with any suitable device, such as the incubator <NUM> of <FIG>, the infant care station <NUM> of <FIG>, the infant care station <NUM> of <FIG>, the infant care station 900A of <FIG>, the infant care station 900B of <FIG>, the infant care station <NUM> of <FIG>, or the computing device <NUM> of <FIG>, among others.

In some examples, the method <NUM> can include, at block <NUM>, detecting an open access point as described above in greater detail in relation to block <NUM> of <FIG>. For example, the method <NUM> can include detecting an open access point based on any suitable sensor data obtained or received from sensors located in or adjacent to an infant care station.

The method <NUM> can also include detecting, at block <NUM>, a location of a patient within an infant care station. In some examples, the location of the patient can be determined based on sensor data collected or obtained by accelerometers, radar sensors, light sensors, or the like. The sensors can be coupled to the patient, such as accelerometers coupled to any suitable portion of a patient. In some examples, the sensors can also reside in the infant care station. For example, any light sensors, radar sensors, or the like, can reside in the infant care station and can monitor a location of a patient within an infant care station.

The method <NUM> can also include providing, at block <NUM>, a light indicator in response to detecting the location of the patient is within a threshold distance of the open access point. For example, the method <NUM> can include providing any suitable color light with a lighting system of an infant care station in response to a patient changing location to be within a predetermined threshold distance from an open or unsealed access point.

<FIG> is a block diagram of an example infant care station that can detect a location of a patient and provide an indicator with a lighting system. In some examples, the infant care station can <NUM> can include any number of sensors <NUM> such as a radar sensor, a light sensor, or the like. In some examples, the sensors <NUM> can be coupled or attached to the infant care station <NUM> or coupled to or attached to a patient. The sensors <NUM> can obtain sensor data about the location of a patient and determine if the patient is within a predetermined distance from an open access point.

In some examples, the infant care station <NUM> can include a lighting system <NUM> that can provide an indicator that a patient is within a threshold distance from an open access point. For example, the lighting system <NUM> can have one or more lights <NUM> that provide a color indicator representing a presence of a patient within a predetermined distance from an open access point. In some examples, the lighting system <NUM> can turn off the one or more lights <NUM> in response to detecting the patient is no longer within a predetermined distance from an open access point.

In one example, an infant care station can include a lighting system, at least one access point, and a processor that can detect that the at least one access point is open. The processor can also provide, using the lighting system, a first color light in response to the detecting that the at least one access point is open, and provide the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point being open.

Alternatively, or in addition, the processor can detect a change in an environmental characteristic from a microenvironment of the infant care station, wherein the environmental characteristic comprises a temperature of the microenvironment, a humidity level of the microenvironment, or an oxygen level of the microenvironment. Alternatively, or in addition, the processor can provide a third color with the lighting system, wherein the third color represents the change in the environmental characteristic. Alternatively, or in addition, the processor can change a portion of the lighting system that is illuminated based on the predetermined period of time in which the at least one access point is open.

Alternatively, or in addition, processor can provide an audible alarm after the lighting system has provided the second color for a second period of time. Alternatively, or in addition, the lighting system can be proximate to the at least one access point that is open. Alternatively, or in addition, the processor can automatically initiate an air boost component in the infant care station in response to the detecting that the at least one access point is open. Alternatively, or in addition, the lighting system can be located along an edge of a porthole door, and the processor can illuminate a first portion of the lighting system in response to the detecting that the at least one access point is open and illuminate a second portion of the lighting system in response to the predetermined period of time elapsing with the at least one access point being open.

Alternatively, or in addition, the processor can obtain lighting system data representing the first color light, the second color light, and a time that the access point is open and transmit the lighting system data to a remote device. Alternatively, or in addition, the processor can simultaneously provide two or more different color lights with the lighting system in response to detecting that the at least one access point is open and detecting a reduction in a humidity level of a microenvironment of the infant care station or a reduction in a temperature of the microenvironment of the infant care station.

In another example, a method for illuminating an infant care station can include detecting that at least one access point is open using a sensor in the infant care station, providing, using a lighting system, a first color light in response to the detecting that the at least one access point is open, and providing the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point being open.

Alternatively, or in addition, the method can include detecting a change in an environmental characteristic from a microenvironment of the infant care station, wherein the environmental characteristic comprises a temperature of the microenvironment, a humidity level of the microenvironment, or an oxygen level of the microenvironment. Alternatively, or in addition, the method can include providing a third color with the lighting system, wherein the third color represents the change in the environmental characteristic. Alternatively, or in addition, the method can include changing a portion of the lighting system that is illuminated based on the predetermined period of time in which the at least one access point is open. Alternatively, or in addition, the method can include providing an audible alarm after the lighting system has provided the second color for a second period of time.

Alternatively, or in addition, the lighting system is proximate to the at least one access point that is open. Alternatively, or in addition, the method can include automatically initiating an air boost component in the infant care station in response to the detecting that the at least one access point is open. Alternatively, or in addition, the lighting system is located along an edge of a porthole door, and the method can include illuminating a first portion of the lighting system in response to the detecting that the at least one access point is open and illuminating a second portion of the lighting system in response to the predetermined period of time elapsing with the at least one access point being open. Alternatively, or in addition, the method can include obtaining lighting system data representing the first color light, the second color light, and a time that the access point is open and transmitting the lighting system data to a remote device.

In another example, a non-transitory machine-readable media can include a plurality of instructions that in response to execution by a processor, cause the processor to detect that the at least one access point is open. The plurality of instructions can also cause the processor to provide, using the lighting system, a first color light in response to the detecting that the at least one access point is open and provide the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point being open. In some examples, the plurality of instructions can cause the processor to obtain lighting system data representing the first color, the second color, and a time that the access point is open and transmit the lighting system data to a remote device.

Claim 1:
An infant care station (<NUM>) comprising:
a lighting system;
at least one access point (<NUM>); and
a processor (<NUM>) configured to:
detect, via one or more sensors, that the at least one access point (<NUM>) is open;
provide, using the lighting system, a first color light in response to the detecting that the at least one access point (<NUM>) is open; and
provide the first color light with a modified brightness or provide a second color light with the lighting system after a predetermined period of time elapses with the at least one access point (<NUM>) being open.