CN219846618U - Ultrasonic equipment host - Google Patents

Abstract

An ultrasonic equipment host relates to the technical field of medical equipment and comprises a host state monitoring unit, a storage medium state monitoring unit, a power supply state monitoring unit, a battery state monitoring unit and a state indicating lamp, wherein the state indicating lamp comprises a first lamp bead, a second lamp bead and a third lamp bead, and whether the ultrasonic equipment host is in a standby state or not and whether a storage medium is in a read-write state or not is characterized by the first lamp bead; the second lamp bead is used for representing whether a power interface is externally connected with a power supply or not; and utilizing the third lamp bead to represent the state of the rechargeable battery. The application uses one tri-color lamp to respectively represent four states of the main machine of the ultrasonic equipment, thereby greatly reducing the cost and improving the integration level of the main machine of the ultrasonic equipment.

Description

Ultrasonic equipment host

Technical Field

The application relates to the technical field of medical equipment, in particular to an ultrasonic equipment host.

Background

Ultrasonic devices typically have a number of indicators, such as an AC power on-site status indicator, a standby status indicator, a hard disk status indicator, etc., and if the ultrasonic device has a battery (e.g., a portable ultrasonic device), the ultrasonic device will typically have a battery status indicator.

Referring to fig. 1, for the portable ultrasonic apparatus which is currently becoming popular, it is provided with such a number of indicator lamps, which not only increases the cost, but also affects the integration level and miniaturization of the apparatus.

Disclosure of Invention

In order to solve the above problems, the present application provides an ultrasound apparatus mainframe, which is described in detail below.

According to a first aspect, in one embodiment there is provided an ultrasound device host comprising: the device comprises a shell, a display screen, an input assembly, a processor, a storage medium, a rechargeable battery, a power supply circuit, a charging circuit, a probe interface, a power interface, a host state monitoring unit, a storage medium state monitoring unit, a power state monitoring unit, a battery state monitoring unit and a state indicator lamp, wherein the display screen, the input assembly, the processor, the storage medium, the rechargeable battery, the power supply circuit, the charging circuit, the probe interface, the power interface, the host state monitoring unit, the storage medium state monitoring unit, the power state monitoring unit, the battery state monitoring unit and the state indicator lamp are arranged on the shell;

the power interface is used for externally connecting a power supply to supply power through the power supply circuit and/or charge the rechargeable battery through the charging circuit;

the rechargeable battery is used for supplying power through the power supply circuit;

the probe interface is used for connecting an ultrasonic probe;

the host state monitoring unit is used for monitoring whether the ultrasonic equipment host is in a standby state and outputting corresponding signals;

The storage medium state monitoring unit is used for monitoring whether the storage medium is in a read-write state or not and outputting corresponding signals;

the power state monitoring unit is used for monitoring whether the power interface is externally connected with a power supply or not and outputting corresponding signals;

the battery state monitoring unit is used for monitoring the state of the rechargeable battery and outputting corresponding signals, and the state of the rechargeable battery comprises an electric quantity state and a charge and discharge state;

the status indicator lamp comprises a lamp shell, a first lamp bead, a second lamp bead and a third lamp bead, wherein the first lamp bead, the second lamp bead and the third lamp bead are arranged in the lamp shell and can respectively emit first color light, second color light and third color light; the on-off state of the first lamp bead is used for representing whether the ultrasonic equipment host is in a standby state or not and whether the storage medium is in a read-write state or not; the on-off state of the second lamp bead is used for representing whether the power interface is externally connected with a power supply or not; the on-off state of the third light bead is used for representing the state of the rechargeable battery.

In one embodiment, the on-off state includes at least two of on, off, and blinking.

In an embodiment, the on-off state of the first light bead includes flashing at a first frequency, flashing at a second frequency, and turning off, and is used for characterizing that the storage medium is in a read-write state, the ultrasonic equipment host is in a standby state, and the ultrasonic equipment host is in a non-standby state and the storage medium is in a non-read-write state; wherein the first frequency is greater than the second frequency; or the on-off state of the first lamp bead comprises on, flash and off, and is respectively used for representing that the storage medium is in a read-write state, the ultrasonic equipment host is in a standby state, the ultrasonic equipment host is in a non-standby state and the storage medium is in an unread-write state;

And/or the number of the groups of groups,

the on-off state of the second lamp bead comprises on and off states, and is respectively used for representing that the power interface is externally connected with a power supply and the power interface is not externally connected with the power supply;

and/or the number of the groups of groups,

the on-off state of the third lamp bead comprises on, flickering and off; the lighting of the third lamp bead is used for representing that the electric quantity of the rechargeable battery is sufficient or the battery is charged fully, the flashing of the third lamp bead is used for representing that the electric quantity of the rechargeable battery is insufficient or the battery is being charged, and the turning-off of the third lamp bead is used for representing that the electric quantity of the rechargeable battery is zero or the battery fails.

In an embodiment, the ultrasonic equipment host further comprises a first driving signal generating circuit, a second driving signal generating circuit and a third driving signal generating circuit;

the first driving signal generating circuit is respectively connected with the host state monitoring unit and the storage medium state monitoring unit in a signal manner and is used for controlling the on-off state of the first lamp beads according to the signals of the host state monitoring unit and the storage medium state monitoring unit;

the second driving signal generating circuit is in signal connection with the power state monitoring unit and is used for controlling the on-off state of the second lamp beads according to the signal of the power state monitoring unit;

The third driving signal generating circuit is in signal connection with the battery state monitoring unit and is used for controlling the on-off state of the third lamp beads according to the signal of the battery state monitoring unit.

According to a second aspect, in one embodiment there is provided an ultrasound device host comprising: the system comprises a storage medium, a host state monitoring unit, a storage medium state monitoring unit, a first driving signal generating circuit and an indicator lamp;

the indicator lamp comprises a lamp shell and a first lamp bead; the first lamp beads are arranged in the lamp housing and can emit first color light;

the host state monitoring unit is used for monitoring whether the ultrasonic equipment host is in a standby state or not and outputting a first host state signal for representing that the ultrasonic equipment host is in the standby state or a second host state signal for representing that the ultrasonic equipment host is in a non-standby state;

the first driving signal generating circuit can generate three driving signals, and when different driving signals drive the first lamp beads, the first lamp beads can be in different on-off states so as to be used for representing whether the ultrasonic equipment host is in a standby state or not and whether the storage medium is in a read-write state or not: when the first signal of the host state is received, the first driving signal generating circuit generates a preset driving signal to drive the first lamp beads; when the host state second signal and the storage medium first signal are received, the first driving signal generating circuit generates another preset driving signal to drive the first lamp beads; when the host state second signal and the storage medium second signal are received, the first driving signal generating circuit generates a preset driving signal to drive the first lamp beads.

In an embodiment, when the first signal of the host state is received, the first driving signal generating circuit generates a preset driving signal to drive the first lamp bead, so that the first lamp bead flashes at the second frequency to represent that the ultrasonic equipment host is in a standby state;

when the second signal of the host state and the first signal of the storage medium are received, the first driving signal generating circuit generates another preset driving signal to drive the first lamp beads, so that the first lamp beads flash at a first frequency to represent that the storage medium is in a read-write state;

when the second signal of the host state and the second signal of the storage medium are received, the first driving signal generating circuit generates a preset driving signal to drive the first lamp beads, so that the first lamp beads are extinguished, and the ultrasonic equipment host is characterized to be in a non-standby state and the storage medium is characterized to be in a non-read-write state.

In an embodiment, the ultrasound device host further comprises: the power supply system comprises a power interface, a power supply circuit, a power state monitoring unit and a second driving signal generating circuit;

the power interface is used for externally connecting a power supply to supply power through the power supply circuit;

The power state monitoring unit is used for monitoring whether the power interface is externally connected with a power supply or not and outputting an AC in-place signal used for representing that the power interface is externally connected with the power supply or an AC out-of-place signal used for representing that the power interface is not externally connected with the power supply;

the indicator light further comprises a second lamp bead; the second lamp beads are arranged in the lamp housing and can emit second color light;

the second driving signal generating circuit can generate two driving signals, and when different driving signals drive the second lamp beads, the second lamp beads can be in different on-off states so as to be used for representing whether the power interface is externally connected with a power supply or not: when the AC in-place signal is received, the second driving signal generating circuit generates a preset driving signal to drive the second lamp beads; when the AC unoccupied signal is received, the second driving signal generating circuit generates another preset driving signal to drive the second lamp beads.

In an embodiment, when the AC in-place signal is received, the second driving signal generating circuit generates a preset driving signal to drive the second lamp bead, so that the second lamp bead is lightened, and the power interface is characterized in that a power supply is externally connected;

When the AC unoccupied signal is received, the second driving signal generating circuit generates another preset driving signal to drive the second lamp beads, so that the second lamp beads are extinguished, and the power interface is characterized in that no power is externally connected.

In an embodiment, the ultrasound device host further comprises: the device comprises a power interface, a power supply circuit, a charging circuit, a rechargeable battery, a battery state monitoring unit and a third driving signal generating circuit;

the power interface is used for externally connecting a power supply to supply power through the power supply circuit and/or charge the rechargeable battery through the charging circuit;

the rechargeable battery is used for supplying power through the power supply circuit;

the battery state monitoring unit is used for monitoring the state of the rechargeable battery and outputting a battery first signal used for representing that the rechargeable battery is in a fault state, a battery second signal used for representing that the rechargeable battery is in a charged state but is not fully charged, a battery third signal used for representing that the rechargeable battery is fully charged, a battery fourth signal used for representing that the electric quantity of the rechargeable battery is zero, a battery fifth signal used for representing that the rechargeable battery is in a discharging state and the electric quantity is less than or equal to the electric quantity threshold value, or a battery sixth signal used for representing that the rechargeable battery is in a discharging state and the electric quantity is greater than the electric quantity threshold value;

The indicator light further comprises a third lamp bead; the third lamp bead is arranged in the lamp housing and can emit third color light;

the third driving signal generating circuit can generate three driving signals, and when different driving signals drive the third lamp beads, the third lamp beads can be in different on-off states so as to be used for representing the states of the rechargeable battery: when the battery third signal or the battery sixth signal is received, the third driving signal generating circuit generates a preset driving signal to drive the third lamp bead; when the battery second signal or the battery fifth signal is received, the third driving signal generating circuit generates another preset driving signal to drive the third lamp beads; when the first signal of the battery or the third signal of the battery is received, the third driving signal generating circuit generates a preset driving signal to drive the third lamp bead.

In an embodiment, when the third signal of the battery or the sixth signal of the battery is received, the third driving signal generating circuit generates a preset driving signal to drive the third lamp bead, so that the third lamp bead is lightened, and the condition that the rechargeable battery is full of electric quantity or full of battery charge is indicated;

When the second signal of the battery or the fifth signal of the battery is received, the third driving signal generating circuit generates another preset driving signal to drive the third lamp beads, so that the third lamp beads flash to indicate that the rechargeable battery is in low electric quantity or the battery is being charged;

when the first signal of the battery or the third signal of the battery is received, the third driving signal generating circuit generates a preset driving signal to drive the third lamp beads, so that the third lamp beads are extinguished, and the rechargeable battery is characterized in that the electric quantity of the rechargeable battery is zero or the battery fails.

According to the ultrasonic equipment host machine in the embodiment, whether the ultrasonic equipment host machine is in a standby state and whether the storage medium is in a read-write state can be indicated by the first lamp bead, so that whether the ultrasonic equipment host machine is in the standby state and whether the storage medium is in the read-write state can be indicated by one lamp bead, the number of the indication lamps is reduced, the cost is reduced, and the integration level of the equipment is improved;

according to the above embodiment, the ultrasonic equipment host comprises a status indicator lamp, wherein the status indicator lamp comprises a lamp housing, a first lamp bead, a second lamp bead and a third lamp bead, and the first lamp bead, the second lamp bead and the third lamp bead are arranged in the lamp housing and can respectively emit first color light, second color light and third color; by referring to the status indicator lamp, the three lamp beads are integrated in the lamp housing, so that the integration level of the main machine of the ultrasonic equipment is improved.

Drawings

FIG. 1 is a schematic perspective view of a host machine of an ultrasound device in one embodiment;

fig. 2 is a schematic diagram of a driving principle of an indicator lamp of an ultrasonic equipment host in an embodiment;

FIG. 3 is a schematic diagram of the structure of an ultrasound device host according to one embodiment;

FIG. 4 is a schematic diagram of another embodiment of an ultrasound device host;

FIG. 5 is a schematic diagram of the structure of a host of an ultrasound device according to yet another embodiment;

fig. 6 is a schematic structural diagram of a status indicator light of an ultrasound apparatus host according to an embodiment.

Detailed Description

The application will be described in further detail below with reference to the drawings by means of specific embodiments. Wherein like elements in different embodiments are numbered alike in association. In the following embodiments, numerous specific details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted, or replaced by other elements, materials, or methods in different situations. In some instances, related operations of the present application have not been shown or described in the specification in order to avoid obscuring the core portions of the present application, and may be unnecessary to persons skilled in the art from a detailed description of the related operations, which may be presented in the description and general knowledge of one skilled in the art.

Furthermore, the described features, operations, or characteristics of the description may be combined in any suitable manner in various embodiments. Also, various steps or acts in the method descriptions may be interchanged or modified in a manner apparent to those of ordinary skill in the art. Thus, the various orders in the description and drawings are for clarity of description of only certain embodiments, and are not meant to be required orders unless otherwise indicated.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The term "coupled" as used herein includes both direct and indirect coupling (coupling), unless otherwise indicated.

Taking the ultrasound device host of fig. 1 as an example, it uses 4 discrete LED indicators to indicate the status of AC power in place, standby status, hard disk status and battery status, respectively: the first lamp (which may be called an AC status lamp or an AC in-place indicator lamp) is used for indicating that the AC power supply is in place, when the lamp is on, the AC power supply is in place, and when the lamp is off or not on, the AC power supply is out of place; the standby state is indicated by a second lamp (a standby state lamp or a standby indication lamp is not used), when the lamp is in flash, the current standby state is indicated, and when the lamp is in off or not on, the current non-standby state is indicated; the third lamp (which may be called a hard disk status lamp or a hard disk status indicator lamp) is used for indicating the status of the hard disk, when the lamp is in a slow flashing state, the status of the hard disk is in a read-write state, and when the lamp is out or not in a bright state, the status of the hard disk is not in a read-write state; the battery status is indicated by a fourth lamp (which may be called a battery status lamp or a battery status indicator lamp), which is a two-color lamp (e.g., an orange-green two-color lamp); under the condition that the AC status lamp is on, the battery status lamp is not on, the battery is not charged, the battery status lamp is only orange, the battery is charged but not fully charged, and the battery status lamp is only green, the battery is fully charged; and under the condition that the AC status lamp is off, the battery status lamp is not on, the battery is not powered, the battery status lamp is on only in green, the battery is full, and the battery status lamp is off in orange, the battery is insufficient.

Fig. 2 is a schematic diagram of a control circuit of each LED indicator, and the on-off state (for example, on, off, and blinking) of the lamp is controlled by a control signal (typically, a PWM signal) of each LED indicator.

Each type of state is indicated by using an LED indicator lamp, which affects the integration level and miniaturization of the ultrasonic device and also increases the cost of the ultrasonic device.

The present application has been made in view of the above problems. The applicant studied the relation between the states of the different types and found that the state of standby (i.e. standby or non-standby) and the state of hardware are related, firstly, both types of states only occur in the on or standby state and do not occur in the off state, and secondly, when the device is in standby, the hardware is not in the read-write state, so that the two types of states can share one indicator light, more precisely, a light bead, for example, when the light bead is in the light flash, the current hardware is in the read-write state (when the device is also necessarily in the non-standby state), when the light bead is in the slow flash, the device is in the standby state (when the hardware is necessarily in the non-read-write state), and when the light bead is out, the device is in the non-standby state and the hardware is in the non-read-write state.

In some embodiments, other indicator lights may be considered to be integrated in the structure of the mechanism, for example, a multi-color light may be introduced, for example, three light beads may be introduced, one light bead is shared by two types of status indicators, namely standby and hardware, one light bead indicates an AC in-place status, and one light bead indicates a battery status.

Referring to fig. 3, 4 and 5, in some embodiments, an ultrasound device host is provided, including a housing 101, and one or more of a display screen 102, an input component 103, a processor 104, a storage medium 105, a rechargeable battery 106, a power supply circuit 107, a charging circuit 108, a probe interface 109, a power interface 110, a host status monitoring unit 111, a storage medium status monitoring unit 112, a power status monitoring unit 113, a battery status monitoring unit 114, a status indicator 115, a first driving signal generating circuit 219, a second driving signal generating circuit 220 and a third driving signal generating circuit 221 disposed in the housing 101, for example, fig. 3 is an example of an ultrasound device host including at least a storage medium 105, a host status monitoring unit 111, a storage medium status monitoring unit 112, a first driving signal generating circuit 219 and a status indicator 115 (also referred to as indicator 115), fig. 4 shows an example of an ultrasound apparatus host including at least a housing 101, and a display screen 102, an input module 103, a processor 104, a storage medium 105, a rechargeable battery 106, a power supply circuit 107, a charging circuit 108, a probe interface 109, a power supply interface 110, a host status monitoring unit 111, a storage medium status monitoring unit 112, a power supply status monitoring unit 113, a battery status monitoring unit 114, and a status indicator 115 provided in the housing 101, and fig. 5 shows an ultrasound apparatus host including at least a housing 101, and a display screen 102, an input module 103, a processor 104, a storage medium 105, a rechargeable battery 106, a power supply circuit 107, a charging circuit 108, a probe interface 109, a power supply interface 110, a host status monitoring unit 111, a storage medium status monitoring unit 112, a power supply status monitoring unit 113, a power supply status monitoring unit 110, a display screen 102, an input module 103, a processor 104, a storage medium 105, a rechargeable battery 108, a power supply interface 109, a power supply status monitoring unit 112, a power supply status monitoring unit 113, and a status indicator 115 provided in the housing 101, examples of the battery state monitoring unit 114, the state indicator 115, the first driving signal generation circuit 219, the second driving signal generation circuit 220, and the third driving signal generation circuit 221. The units, components and structures are described below.

In some embodiments, the power interface 110 is configured to be externally powered to provide power via the power circuit 107 and/or to charge the rechargeable battery 106 via the charging circuit 108. In some embodiments, the power source externally connected to the power interface 110 may be a mains supply.

In some embodiments, rechargeable battery 106 is configured to be powered by power supply circuit 107. In some embodiments, the rechargeable battery 106 may be a rechargeable lithium battery.

It can be seen that the power interface 110 is externally connected with a power supply to supply power to the main machine of the ultrasonic equipment, and also can charge the rechargeable battery 106; when the power interface 110 is not externally connected with a power supply, the secondary electricity can be conducted through the rechargeable battery 106.

In some embodiments, the probe interface 109 is used to connect an ultrasound probe.

In some embodiments, the storage medium 105 is used to store data, and the storage medium 105 can be written to and read from data. In some embodiments, storage medium 105 comprises a hard disk.

In some embodiments, the host state monitoring unit 111 is configured to monitor whether the ultrasound device host is in a standby state and output a corresponding signal, for example, output a first host state signal for indicating that the ultrasound device host is in a standby state or a second host state signal for indicating that the ultrasound device host is in a non-standby state. It should be noted that, the standby state and the non-standby state refer to a state of the ultrasound device host after being powered on.

In some embodiments, the storage medium state monitoring unit 112 is configured to monitor whether the storage medium 105 is in a read-write state and output a corresponding signal, for example, a storage medium first signal for indicating that the storage medium 105 is in a read-write state or a storage medium second signal for indicating that the storage medium 105 is in a non-read-write state.

In some embodiments, the power status monitoring unit 113 is configured to monitor whether the power interface 110 is connected to power and output a corresponding signal, for example, an AC in-place signal for indicating that the power interface 110 is connected to power, or an AC out-of-place signal for indicating that the power interface 110 is not connected to power.

In some embodiments, the battery state monitoring unit 114 is configured to detect a state of the rechargeable battery 106 and output a corresponding signal; in some embodiments, the state of the rechargeable battery includes a charge state and a charge-discharge state. In some embodiments, the battery state monitoring unit 114 is configured to detect the state of the rechargeable battery 106 and output a corresponding signal, which may be a battery first signal indicating that the rechargeable battery 106 is in a fault state, a battery second signal indicating that the rechargeable battery 106 is charged but not fully charged, a battery third signal indicating that the rechargeable battery 106 is fully charged, a battery fourth signal indicating that the rechargeable battery 106 is zero, a battery fifth signal indicating that the rechargeable battery 106 is in a discharge state and the charge is less than or equal to the charge threshold, or a battery sixth signal indicating that the rechargeable battery 106 is in a discharge state and the charge is greater than the charge threshold.

The status indicator lamp 115 will be described below.

Referring to fig. 6, the status indicator 115 of some embodiments includes a lamp housing 115a; status indicator 115 of some embodiments may further include one or more of a first light bead 116, a second light bead 117, and a third light bead 118; in some embodiments, the first light bead 116 is capable of emitting a first color light (e.g., orange light); in some embodiments, the second light bead 117 is capable of emitting a second color light (e.g., blue light); in some embodiments, the third light bead 118 is capable of emitting a third color light (e.g., green light). In some embodiments, the status indicator 115 includes light beads disposed within the light housing 115 a. Fig. 5 is an example of the status indicator 115 including three light beads, namely, a first light bead 116, a second light bead 117 and a third light bead 118, where the first light bead 116, the second light bead 117 and the third light bead 118 are all disposed in the light housing 115a, and the status indicator of fig. 5 may be a tri-color light.

In some embodiments, the on-off state of the first light bead 116 is used to characterize whether the ultrasound device host is in a standby state and whether the storage medium is in a read-write state. In some embodiments, the on-off state includes at least two of on, off, and blinking.

In some embodiments, the on-off state of the first beads 116 includes blinking at a first frequency, blinking and off at a second frequency, it being understood that the first and second frequencies are different; in some embodiments, the first frequency is greater than the second frequency; for example, the first frequency of flicker may be perceived as a flash by a person, e.g., 2Hz, and the second frequency of flicker may be perceived as a slow flash by a person, e.g., 0.5Hz. In some embodiments, the first beads 116, when blinking at a first frequency, characterize the storage medium 105 as being in a read-write state; when the first lamp bead 116 flashes at the second frequency, the main machine of the ultrasonic equipment is characterized as being in a standby state; when the first light bead 116 is off, it indicates that the ultrasound device host is in a non-standby state and the storage medium 105 is in an unread-write state.

In some embodiments, the on-off state of the first beads 116 includes on, off, and blinking; when the first lamp bead 116 is on, the storage medium 105 is represented to be in a read-write state; when the first lamp bead 116 flashes, the main machine of the ultrasonic equipment is characterized as being in a standby state; when the first light bead 116 is turned off, it indicates that the ultrasound device host is in a non-standby state and the storage medium 105 is in an unread-write state.

In some embodiments, the first beads 116 may be driven by the first driving signal generation circuit 219.

In some embodiments, the first driving signal generating circuit 219 is respectively connected to the host status monitoring unit 111 and the storage medium status monitoring unit 112, and is configured to control the on/off states of the first lamp beads 116 according to the signals of the host status monitoring unit 111 and the storage medium status monitoring unit 112.

In some embodiments, the first driving signal generating circuit 219 is capable of generating three driving signals, where different driving signals can enable the first light bead 116 to be in different on/off states when driving the first light bead 116, so as to be used for representing whether the ultrasonic device host is in a standby state and whether the storage medium 105 is in a read/write state; for example: when receiving the first signal of host state, the first driving signal generating circuit 219 generates a preset driving signal to drive the first lamp beads 116; when the host status second signal and the storage medium first signal are received, the first driving signal generating circuit 219 generates another preset driving signal to drive the first lamp beads 116; when the host status second signal and the storage medium second signal are received, the first driving signal generating circuit 219 generates a preset further driving signal to drive the first lamp beads 116.

In one example, when the first signal of the host state is received, the first driving signal generating circuit 219 generates a preset driving signal to drive the first lamp beads 116, so that the first lamp beads 116 flash at the second frequency, which indicates that the host of the ultrasonic device is in the standby state; when the host state second signal and the storage medium first signal are received, the first driving signal generating circuit 219 generates another preset driving signal to drive the first lamp beads 116, so that the first lamp beads 116 flash at the first frequency, which characterizes that the storage medium 105 is in a read-write state; when the host state second signal and the storage medium second signal are received, the first driving signal generating circuit 219 generates a preset further driving signal to drive the first lamp beads 116, so that the first lamp beads 116 are extinguished, and the ultrasonic equipment host is characterized as being in a non-standby state and the storage medium 105 is characterized as being in an unread-write state; it will be appreciated that the first frequency and the second frequency are different; in some embodiments, the first frequency is greater than the second frequency.

In some embodiments, the on/off state of the second light bead 117 is used to indicate whether the power interface is externally connected with a power supply. In some embodiments, the on-off state includes at least two of on, off, and blinking.

In some embodiments, the on-off state of the second light bead 117 includes on and off; when the second lamp bead 117 is on, the power supply interface 110 is externally connected with a power supply, and when the second lamp bead 117 is off, the power supply interface 110 is not externally connected with the power supply.

In some embodiments, the second lamp bead 117 may be driven by the second driving signal generating circuit 220.

In some embodiments, the second driving signal generating circuit 117 is connected to the power state monitoring unit 113 in a signal manner, and is configured to control the on/off state of the second lamp bead 117 according to the signal of the power state monitoring unit 113.

In some embodiments, the second driving signal generating circuit 220 can generate two driving signals, and when the different driving signals drive the second lamp beads 117, the second lamp beads 117 can be in different on/off states, so as to be used for representing whether the power interface 110 is externally connected with a power supply; for example: when receiving the AC in-place signal, the second driving signal generating circuit 220 generates a preset driving signal to drive the second lamp beads 117; when the AC absent signal is received, the second driving signal generating circuit 220 generates another preset driving signal to drive the second lamp beads 117.

In one example, when the AC in-place signal is received, the second driving signal generating circuit 220 generates a preset driving signal to drive the second lamp bead 117, so that the second lamp bead 117 is turned on, which indicates that the power interface 110 is externally connected with a power supply; when the AC absent signal is received, the second driving signal generating circuit 220 generates another preset driving signal to drive the second lamp beads 117, so that the second lamp beads 117 are turned off, which indicates that the power interface 110 is not externally connected with a power supply.

In some embodiments, the on-off state of the third light bead 118 is used to characterize the state of the rechargeable battery. In some embodiments, the on-off state includes at least two of on, off, and blinking.

In some embodiments, the on-off state of the third beads 118 includes on, off, and blinking; when the third light bulb 118 is on, it is used to indicate that the rechargeable battery 106 is full of charge or that the battery is fully charged; when the third light beads 118 flash, they are used to indicate that the rechargeable battery 106 is low in power or that the battery is being charged; the deactivation of the third light bulb 118 is used to characterize the rechargeable battery 106 as having zero charge or a battery failure. As can be appreciated, when the external power source is connected, the third lamp bead 118 is turned on to indicate that the battery is charged fully, the third lamp bead 118 is turned on to indicate that the battery is being charged, and the third lamp bead 118 is turned off to indicate that the battery is faulty; when no external power is connected, the third lamp bead 118 is on for representing that the electric quantity of the rechargeable battery 106 is sufficient, the third lamp bead 118 is flashing for representing that the electric quantity of the rechargeable battery 106 is insufficient, and the third lamp bead 118 is off for representing that the electric quantity of the rechargeable battery 106 is zero. In some examples, whether the power is externally connected may be determined by the on/off state of the second lamp bead 117.

In some embodiments, the third beads 118 may be driven by the third driving signal generating circuit 221.

In some embodiments, the third driving signal generating circuit 221 is signal-connected to the battery state monitoring unit 114, and is configured to control the on/off state of the third lamp bead 118 according to the signal of the battery state monitoring unit 114.

In some embodiments, the third driving signal generating circuit 221 can generate three driving signals, and different driving signals can enable the third light bead 118 to be in different on/off states when driving the third light bead, so as to be used for representing the state of the rechargeable battery 106: when the battery third signal or the battery sixth signal is received, the third driving signal generating circuit 221 generates a preset driving signal to drive the third lamp beads 118; when the battery second signal or the battery fifth signal is received, the third driving signal generating circuit 221 generates another preset driving signal to drive the third lamp beads 118; when the battery first signal or the battery third signal is received, the third driving signal generating circuit 221 generates a preset further driving signal to drive the third lamp beads 118.

In one example, when the battery third signal or the battery sixth signal is received, the third driving signal generating circuit 221 generates a preset driving signal to drive the third light beads 118, so that the third light beads 118 are lightened, which indicates that the rechargeable battery 106 is fully charged or the battery is fully charged; when the second signal of the battery or the fifth signal of the battery is received, the third driving signal generating circuit 221 generates another preset driving signal to drive the third lamp beads 118, so that the third lamp beads 118 flash, which indicates that the rechargeable battery 106 is under-charged or the battery is being charged; when the first battery signal or the third battery signal is received, the third driving signal generating circuit 221 generates a preset further driving signal to drive the third light bulb 118, so that the third light bulb 118 is turned off, which indicates that the electric quantity of the rechargeable battery 106 is zero or the battery fails.

It should be noted that, how to control the on/off state of the lamp bead is the prior art, for example, how to control the on/off and blinking of the lamp bead, which is achieved by changing the duty ratio of the PWM signal, the present application does not improve this.

The ultrasonic equipment host machine of some embodiments can indicate whether the ultrasonic equipment host machine is in a standby state and whether the storage medium is in a read-write state through the first lamp bead, so that whether the ultrasonic equipment host machine is in the standby state and whether the storage medium is in the read-write state can indicate corresponding states through one lamp bead.

The ultrasonic equipment host comprises a status indicator lamp, wherein the status indicator lamp comprises a lamp shell, a first lamp bead, a second lamp bead and a third lamp bead, and the first lamp bead, the second lamp bead and the third lamp bead are arranged in the lamp shell and can respectively emit first color light, second color light and third color; by referring to the status indicator lamp, three lamp beads are integrated in one lamp housing, so that the integration level of the main machine of the ultrasonic equipment is improved.

Reference is made to various exemplary embodiments herein. However, those skilled in the art will recognize that changes and modifications may be made to the exemplary embodiments without departing from the scope herein. For example, the various operational steps and components used to perform the operational steps may be implemented in different ways (e.g., one or more steps may be deleted, modified, or combined into other steps) depending on the particular application or taking into account any number of cost functions associated with the operation of the system.

In the above embodiments, it may be implemented in whole or in part by software, hardware, firmware, or any combination thereof. Additionally, as will be appreciated by one of skill in the art, the principles herein may be reflected in a computer program product on a computer readable storage medium preloaded with computer readable program code. Any tangible, non-transitory computer readable storage medium may be used, including magnetic storage devices (hard disks, floppy disks, etc.), optical storage devices (CD-to-ROM, DVD, blu-Ray disks, etc.), flash memory, and/or the like. These computer program instructions may be loaded onto a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions which execute on the computer or other programmable data processing apparatus create means for implementing the functions specified. These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including means which implement the function specified. The computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified.

While the principles herein have been shown in various embodiments, many modifications of structure, arrangement, proportions, elements, materials, and components, which are particularly adapted to specific environments and operative requirements, may be used without departing from the principles and scope of the present disclosure. The above modifications and other changes or modifications are intended to be included within the scope of this document.

The foregoing detailed description has been described with reference to various embodiments. However, those skilled in the art will recognize that various modifications and changes may be made without departing from the scope of the present disclosure. Accordingly, the present disclosure is to be considered as illustrative and not restrictive in character, and all such modifications are intended to be included within the scope thereof. Also, advantages, other advantages, and solutions to problems have been described above with regard to various embodiments. The benefits, advantages, solutions to problems, and any element(s) that may cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as a critical, required, or essential feature. The terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, system, article, or apparatus. Furthermore, the term "couple" and any other variants thereof are used herein to refer to physical connections, electrical connections, magnetic connections, optical connections, communication connections, functional connections, and/or any other connection.

Those skilled in the art will recognize that many changes may be made to the details of the above-described embodiments without departing from the underlying principles of the application. Accordingly, the scope of the application should be determined only by the following claims.

Claims (10)

1. An ultrasound device host machine, comprising: the device comprises a shell, a display screen, an input assembly, a processor, a storage medium, a rechargeable battery, a power supply circuit, a charging circuit, a probe interface, a power interface, a host state monitoring unit, a storage medium state monitoring unit, a power state monitoring unit, a battery state monitoring unit and a state indicator lamp, wherein the display screen, the input assembly, the processor, the storage medium, the rechargeable battery, the power supply circuit, the charging circuit, the probe interface, the power interface, the host state monitoring unit, the storage medium state monitoring unit, the power state monitoring unit, the battery state monitoring unit and the state indicator lamp are arranged on the shell;

the power interface is used for externally connecting a power supply to supply power through the power supply circuit and/or charge the rechargeable battery through the charging circuit;

the rechargeable battery is used for supplying power through the power supply circuit;

the probe interface is used for connecting an ultrasonic probe;

the host state monitoring unit is used for monitoring whether the ultrasonic equipment host is in a standby state and outputting corresponding signals;

the storage medium state monitoring unit is used for monitoring whether the storage medium is in a read-write state or not and outputting corresponding signals;

The power state monitoring unit is used for monitoring whether the power interface is externally connected with a power supply or not and outputting corresponding signals;

the battery state monitoring unit is used for monitoring the state of the rechargeable battery and outputting corresponding signals, and the state of the rechargeable battery comprises an electric quantity state and a charge and discharge state;

the status indicator lamp comprises a lamp shell, a first lamp bead, a second lamp bead and a third lamp bead, wherein the first lamp bead, the second lamp bead and the third lamp bead are arranged in the lamp shell and can respectively emit first color light, second color light and third color light; the on-off state of the first lamp bead is used for representing whether the ultrasonic equipment host is in a standby state or not and whether the storage medium is in a read-write state or not; the on-off state of the second lamp bead is used for representing whether the power interface is externally connected with a power supply or not; the on-off state of the third light bead is used for representing the state of the rechargeable battery.

2. The ultrasound device host of claim 1, wherein the on-off state comprises at least two of on, off, and blinking.

3. The ultrasound device host machine of claim 2, wherein:

the on-off state of the first lamp bead comprises the state of flashing at a first frequency, flashing at a second frequency and off, and is respectively used for representing that the storage medium is in a read-write state, the ultrasonic equipment host is in a standby state, the ultrasonic equipment host is in a non-standby state and the storage medium is in a non-read-write state; wherein the first frequency is greater than the second frequency; or the on-off state of the first lamp bead comprises on, flash and off, and is respectively used for representing that the storage medium is in a read-write state, the ultrasonic equipment host is in a standby state, the ultrasonic equipment host is in a non-standby state and the storage medium is in an unread-write state;

And/or the number of the groups of groups,

the on-off state of the second lamp bead comprises on and off states, and is respectively used for representing that the power interface is externally connected with a power supply and the power interface is not externally connected with the power supply;

and/or the number of the groups of groups,

the on-off state of the third lamp bead comprises on, flickering and off; the lighting of the third lamp bead is used for representing that the electric quantity of the rechargeable battery is sufficient or the battery is charged fully, the flashing of the third lamp bead is used for representing that the electric quantity of the rechargeable battery is insufficient or the battery is being charged, and the turning-off of the third lamp bead is used for representing that the electric quantity of the rechargeable battery is zero or the battery fails.

4. The ultrasound device host of claim 1, further comprising a first drive signal generation circuit, a second drive signal generation circuit, and a third drive signal generation circuit;

the first driving signal generating circuit is respectively connected with the host state monitoring unit and the storage medium state monitoring unit in a signal manner and is used for controlling the on-off state of the first lamp beads according to the signals of the host state monitoring unit and the storage medium state monitoring unit;

the second driving signal generating circuit is in signal connection with the power state monitoring unit and is used for controlling the on-off state of the second lamp beads according to the signal of the power state monitoring unit;

The third driving signal generating circuit is in signal connection with the battery state monitoring unit and is used for controlling the on-off state of the third lamp beads according to the signal of the battery state monitoring unit.

5. An ultrasound device host machine, comprising: the system comprises a storage medium, a host state monitoring unit, a storage medium state monitoring unit, a first driving signal generating circuit and an indicator lamp;

the indicator lamp comprises a lamp shell and a first lamp bead; the first lamp beads are arranged in the lamp housing and can emit first color light;

the host state monitoring unit is used for monitoring whether the ultrasonic equipment host is in a standby state or not and outputting a first host state signal for representing that the ultrasonic equipment host is in the standby state or a second host state signal for representing that the ultrasonic equipment host is in a non-standby state;

the storage medium state monitoring unit is used for monitoring whether the storage medium is in a read-write state or not and outputting a storage medium first signal used for representing that the storage medium is in the read-write state or a storage medium second signal used for representing that the storage medium is in a non-read-write state;

the first driving signal generating circuit can generate three driving signals, and when different driving signals drive the first lamp beads, the first lamp beads can be in different on-off states so as to be used for representing whether the ultrasonic equipment host is in a standby state or not and whether the storage medium is in a read-write state or not: when the first signal of the host state is received, the first driving signal generating circuit generates a preset driving signal to drive the first lamp beads; when the host state second signal and the storage medium first signal are received, the first driving signal generating circuit generates another preset driving signal to drive the first lamp beads; when the host state second signal and the storage medium second signal are received, the first driving signal generating circuit generates a preset driving signal to drive the first lamp beads.

6. The ultrasound device host machine of claim 5, wherein:

when the first signal of the host state is received, the first driving signal generating circuit generates a preset driving signal to drive the first lamp beads, so that the first lamp beads flash at a second frequency, and the host of the ultrasonic equipment is characterized as being in a standby state;

when the second signal of the host state and the first signal of the storage medium are received, the first driving signal generating circuit generates another preset driving signal to drive the first lamp beads, so that the first lamp beads flash at a first frequency to represent that the storage medium is in a read-write state;

when the second signal of the host state and the second signal of the storage medium are received, the first driving signal generating circuit generates a preset driving signal to drive the first lamp beads, so that the first lamp beads are extinguished, and the ultrasonic equipment host is characterized to be in a non-standby state and the storage medium is characterized to be in a non-read-write state.

7. The ultrasound device host machine of claim 5, further comprising: the power supply system comprises a power interface, a power supply circuit, a power state monitoring unit and a second driving signal generating circuit;

The power interface is used for externally connecting a power supply to supply power through the power supply circuit;

the power state monitoring unit is used for monitoring whether the power interface is externally connected with a power supply or not and outputting an AC in-place signal used for representing that the power interface is externally connected with the power supply or an AC out-of-place signal used for representing that the power interface is not externally connected with the power supply;

the indicator light further comprises a second lamp bead; the second lamp beads are arranged in the lamp housing and can emit second color light;

the second driving signal generating circuit can generate two driving signals, and when different driving signals drive the second lamp beads, the second lamp beads can be in different on-off states so as to be used for representing whether the power interface is externally connected with a power supply or not: when the AC in-place signal is received, the second driving signal generating circuit generates a preset driving signal to drive the second lamp beads; when the AC unoccupied signal is received, the second driving signal generating circuit generates another preset driving signal to drive the second lamp beads.

8. The ultrasound device host machine of claim 7, wherein:

when the AC in-place signal is received, the second driving signal generating circuit generates a preset driving signal to drive the second lamp beads, so that the second lamp beads are lightened, and the power interface is characterized in that a power supply is externally connected;

When the AC unoccupied signal is received, the second driving signal generating circuit generates another preset driving signal to drive the second lamp beads, so that the second lamp beads are extinguished, and the power interface is characterized in that no power is externally connected.

9. The ultrasound device host machine of claim 5, further comprising: the device comprises a power interface, a power supply circuit, a charging circuit, a rechargeable battery, a battery state monitoring unit and a third driving signal generating circuit;

the power interface is used for externally connecting a power supply to supply power through the power supply circuit and/or charge the rechargeable battery through the charging circuit;

the rechargeable battery is used for supplying power through the power supply circuit;

the battery state monitoring unit is used for monitoring the state of the rechargeable battery and outputting a battery first signal used for representing that the rechargeable battery is in a fault state, a battery second signal used for representing that the rechargeable battery is in a charged state but is not fully charged, a battery third signal used for representing that the rechargeable battery is fully charged, a battery fourth signal used for representing that the electric quantity of the rechargeable battery is zero, a battery fifth signal used for representing that the rechargeable battery is in a discharging state and the electric quantity is less than or equal to an electric quantity threshold value, or a battery sixth signal used for representing that the rechargeable battery is in a discharging state and the electric quantity is greater than the electric quantity threshold value;

The indicator light further comprises a third lamp bead; the third lamp bead is arranged in the lamp housing and can emit third color light;

the third driving signal generating circuit can generate three driving signals, and when different driving signals drive the third lamp beads, the third lamp beads can be in different on-off states so as to be used for representing the states of the rechargeable battery: when the battery third signal or the battery sixth signal is received, the third driving signal generating circuit generates a preset driving signal to drive the third lamp bead; when the battery second signal or the battery fifth signal is received, the third driving signal generating circuit generates another preset driving signal to drive the third lamp beads; when the first signal of the battery or the third signal of the battery is received, the third driving signal generating circuit generates a preset driving signal to drive the third lamp bead.

10. The ultrasound device host machine of claim 9, wherein:

when the third signal of the battery or the sixth signal of the battery is received, the third driving signal generating circuit generates a preset driving signal to drive the third lamp beads, so that the third lamp beads are lightened, and the condition that the rechargeable battery is full in electric quantity or full in battery charging is represented;

When the second signal of the battery or the fifth signal of the battery is received, the third driving signal generating circuit generates another preset driving signal to drive the third lamp beads, so that the third lamp beads flash to indicate that the rechargeable battery is in low electric quantity or the battery is being charged;

when the first signal of the battery or the third signal of the battery is received, the third driving signal generating circuit generates a preset driving signal to drive the third lamp beads, so that the third lamp beads are extinguished, and the rechargeable battery is characterized in that the electric quantity of the rechargeable battery is zero or the battery fails.