CN110412881B - Separated mobile intelligent system and operation method and base device thereof - Google Patents

Abstract

The invention provides a separated mobile intelligent system, an operation method thereof and a base device. The host device includes: the microphone comprises a first connecting port, a microphone and a first control device. The microphone is used for receiving the voice command to generate a voice signal. The first control device is coupled to the first connection port and the microphone for providing a control signal according to the voice signal. The host device is detachably mounted on the base device, wherein the base device has a plurality of operation modes and comprises a second connection port. The second connection port is used for being coupled with the first connection port and receiving a control signal from the host device, wherein the base device connected with the host device executes a corresponding operation mode according to the control signal.

Description

Separated mobile intelligent system and operation method and base device thereof

Technical Field

The present invention relates to an intelligent system and an operating method thereof, and more particularly, to a separated mobile intelligent system and an operating method thereof and a base device.

Background

With the continuous progress of science and technology, various intelligent electronic devices are becoming popular in daily life, such as intelligent sound boxes, intelligent lighting devices, and so on. However, as shown in fig. 1A, the conventional intelligent electronic device SD includes a control portion for performing operations, such as processing of a wafer, and the like, which is referred to as a control circuit HD. The control circuit HD is often integrally mounted inside the intelligent electronic device SD, so that the user cannot freely replace other parts of the intelligent electronic device SD with only the control circuit HD. Therefore, each intelligent electronic device SD needs to be provided with its own control circuit HD, but when a failure occurs, the user needs to replace the whole intelligent electronic device SD, which increases the production and maintenance costs. In addition, since the control circuit HD and the intelligent electronic device SD cannot be separated, a user cannot use the same control circuit HD to match different electronic devices depending on the requirement, which results in inflexible application.

Disclosure of Invention

The invention provides a separated mobile intelligent system, an operation method thereof and a base device, which can provide a detachable host device and one or more base devices with the same host device, so that a user can replace the base device.

The invention provides a separated mobile intelligent system, which comprises a host device and at least one base device. The host device includes: the microphone comprises a first connecting port, a microphone and a first control device. The microphone is used for receiving the voice command to generate a voice signal. The first control device is coupled to the first connection port and the microphone for providing a control signal according to the voice signal. The host device is detachably mounted to the base device, wherein the base device has a plurality of operating modes and includes a second connection port. The second connection port is used for being coupled with the first connection port and receiving a control signal from the host device, wherein the base device connected with the host device executes a corresponding operation mode according to the control signal.

In an embodiment of the invention, the host device in the separated mobile intelligent system further includes a first memory and the base device further includes a second memory, wherein the first memory stores a lookup table, the lookup table records a plurality of reference identification codes and a plurality of corresponding categories, the second memory stores a product identification code of the base device, and the first control device compares the product identification code with the lookup table to determine the category of the base device.

In an embodiment of the invention, the first memory in the split mobile intelligent system stores a plurality of product driving signals, and the first control device selects one of the product driving signals to drive the base device according to the product identification code.

In an embodiment of the invention, the host device in the split mobile intelligent system further includes a wireless communication interface. The wireless communication interface is coupled with the first control device and the cloud server, wherein the first control device transmits the voice signal to the cloud server through the wireless communication interface, the cloud server generates a control signal according to the voice signal, and the host device receives the control signal through the wireless communication interface.

In an embodiment of the invention, the base in the separated mobile intelligent system is a speaker, and the host device further receives the sound source signal from the cloud server according to the voice signal so that the speaker plays the sound source signal.

In an embodiment of the invention, the host device in the separated mobile intelligent system includes a bottom surface connected to the base device, and the base device has a supporting surface connected to the bottom surface, wherein the host device determines whether to boot up according to a relative rotation angle between the bottom surface and the supporting surface.

In an embodiment of the invention, the first connection port in the separated mobile intelligent system is disposed on the bottom surface and has a first area, and the second connection port is disposed on the carrying surface and has a second area, wherein when the first area and the second area are at least partially overlapped, the host device is powered on.

In an embodiment of the invention, the base device in the split-type mobile intelligent system further includes a second control device, and the second control device is coupled to the second connection port and enables the base device to execute a corresponding operation mode according to the control signal.

In an embodiment of the invention, the base device in the separated mobile intelligent system further includes a power device for providing power to the host device through the second connection port.

In an embodiment of the invention, the base in the separated mobile intelligent system is a speaker, the host device further includes a first memory for storing a plurality of audio signals, and the host device further selects one of the audio signals according to the voice signal and enables the speaker to play the audio signal.

In an embodiment of the invention, the operation modes in the split mobile intelligent system include a start-up mode, a standby mode, a wake-up mode, a power-off mode, a home appliance function control mode, a lighting mode, or a music playing mode.

An embodiment of the present invention provides a method for operating a split-type mobile intelligent system, wherein the split-type mobile intelligent system includes a host device and at least one base device, and the base device has a plurality of operation modes, the method includes: detachably mounting the host device to the base device; receiving a voice command by a host device to generate a voice signal; providing, by the host device, a control signal according to the voice signal; and executing the corresponding operation mode by the base device according to the control signal.

In an embodiment of the present invention, a base device, in which a host device is detachably mounted on the base device, includes a connection port and a control device. The connection port is used for connecting a host device. The control device is coupled to the connection port and configured to control the base device to execute one of a plurality of operation modes, wherein the control device receives a control signal from the host device through the connection port, the control signal is generated by the host device according to the voice command, and the base device executes the corresponding operation mode according to the control signal.

Based on the above, the separated mobile intelligent system, the operation method thereof and the base device of the embodiment of the invention can provide a detachable host device and at least one base device. The host device is installed on the replaceable base device and has a voice recognition function, and can receive voice commands of a user and control the connected base device to execute a corresponding operation mode according to the voice commands.

In order to make the aforementioned and other features and advantages of the invention more comprehensible, embodiments accompanied with figures are described in detail below.

Drawings

FIG. 1A is a schematic diagram of a prior art intelligent electronic device;

FIG. 1B is a diagram of a split mobile intelligence system, in accordance with an embodiment of the present invention;

FIG. 2 is a flow diagram of a method of operation of a split mobile intelligent system, in accordance with an embodiment of the present invention;

fig. 3A and 3B are schematic views illustrating an installation state of a split mobile intelligent system according to an embodiment of the invention;

fig. 4 is a schematic diagram illustrating a host device and a plurality of base devices according to an embodiment of the invention;

fig. 5A and 5B are schematic diagrams illustrating an on/off state of a separated mobile intelligent system according to an embodiment of the present invention;

FIG. 6 is a block diagram of a split mobile intelligent system according to an embodiment of the invention;

FIG. 7 is a flow diagram of a method of operation of a split mobile intelligent system in accordance with an embodiment of the present invention;

FIG. 8 is a diagram illustrating a host device and a plurality of different types of base devices according to an embodiment of the invention;

fig. 9 is a block diagram of a split mobile intelligent system according to another embodiment of the invention.

Description of the reference numerals

100: separated mobile intelligent system

110: host device

112: bottom surface

114: first region

116: first magnetic connecting part

120. 120', 130, 140, 150, 820: base device

122: bearing surface

124: second region

126: second magnetic connecting part

200: host device

210: first control device

220: microphone (CN)

230: first connection port

240: first memory

250: wireless communication interface

260: battery with a battery cell

300: base device

310: second control device

320: power supply device

330: second connecting port

340: second memory

CW: conducting wire

CLS: cloud server

LT: lookup table

HD: control circuit

U: user's hand

S: voice commands

SD: intelligent electronic device

VM: voice processing module

S210 to S240, S710 to S780: operation steps of separated mobile intelligent system

θ: angle of rotation

Detailed Description

Fig. 1B is a schematic diagram of a separated mobile intelligent system according to an embodiment of the invention, and fig. 2 is a flowchart of an operation method of the separated mobile intelligent system according to an embodiment of the invention. The operation method of fig. 2 is applicable to all embodiments of the present specification, and the following describes an embodiment of the separated mobile intelligent system 100 and the operation method thereof in combination with the elements of fig. 1B.

The split mobile intelligent system 100 includes a host device 110 and a base device 120, wherein the host device 110 is detachably assembled to at least one base device. In fig. 1B, the at least one base unit is a plurality of base units 120, wherein each base unit 120 has a plurality of operating modes. Here, fig. 1B only shows the host device 110 and the connected base devices 120, but the invention is not limited to the type and number of the base devices 120. The separated mobile intelligent system 100 has a voice control function, and can allow a user to directly give an instruction by voice through a voice recognition technology to perform an operation, so as to realize an intelligent operation function.

In step S210, the host device 110 is detachably mounted to one of the base devices 120. In step S220, the host device 110 receives the voice command issued by the user to generate a voice signal. The host device 110 may provide a control signal according to the voice signal in step S230, and the base device 120 receives the control signal from the host device 110 and performs a corresponding operation mode according to the control signal in step S240.

It is noted that, for the separated mobile intelligent system 100, the host device 110 and the base device 120 are separable and do not need to be bound to each other. The user may decide which base unit 120 to install the host device 110 to, and then the host device 110 may be replaced on another base unit 120, while the base unit 120 without the host device 110 installed may not implement the operation mode in some embodiments.

Fig. 3A and fig. 3B are schematic views illustrating an installation state of a separated mobile intelligent system according to an embodiment of the invention. In fig. 3A, the host device 110 can be connected to the base device 120 by press-fitting, or the host device 110 can be detached from the base device 120 by press-fitting. For example, the host device 110 may be mounted to the base device 120 by a pogo pin connector. In the embodiment of fig. 3B, the user may also mount the host device 110 to the base device 120 by rotating and snapping. The mounting method includes using a latch mechanism, a rotating connection or magnetic attraction, etc., and the connection method between the host device 110 and the base device 120 is not limited by the present invention.

For example, the base device 120 may be a speaker, and the host device 110 may be a control device with processing capabilities. After the host device 110 is electrically connected to the base device 120, the host device 110 can enable the base device 120 to implement operation modes such as music playing or pausing, song switching, volume increasing or decreasing, fast forwarding or rewinding of music, and muting according to a voice command issued by a user.

Fig. 4 is a schematic diagram illustrating a host device and a plurality of base devices according to an embodiment of the invention. Referring to fig. 4, the host device 110 can be adapted to different base devices. In the present embodiment, the base devices 120, 120', 130, 140, 150 are, for example, speaker box bodies of speakers with various color appearances, sizes or functions. The host device 110, when connected to one of the base devices, may control the switching or operation modes of the speakers, such as a play function or an audio mode, including, for example, one or more of classical, pop, rock, subwoofer, or stereo. For example, the base unit 120 and the base unit 120' are sound boxes of the same design, and the difference is that the housing is different in color. The user may decide which color of base unit the host unit 110 is to be mounted to by preference. Also for example, base unit 120 may be a different size enclosure than base unit 130, base unit 140, or base unit 150, or may have a different frequency range. The base unit 120 may be a mini-speaker, the base unit 130 may be a midrange speaker, the base unit 140 or 150 may be a woofer, and so on. The user can also choose to use different speakers or add the host device 110 to expand the frequency range of the speaker according to the requirement, which is not limited by the invention.

In particular, the base device is not limited to a sound box, and may be a lighting device or other electronic products.

Fig. 5A and 5B are schematic diagrams illustrating an on/off state of a separated mobile intelligent system according to an embodiment of the present invention. Referring to fig. 5A with fig. 3A and 3B, the host device 110 is a disc, but the shape and size are not limited thereto. The host device 110 includes a bottom surface 112 connected to the base device 120, and the base device 120 has a carrying surface 122 connected to the bottom surface 112 of the host device 110. In the present embodiment, the host device 110 can determine whether to boot according to the relative rotation angle between the bottom surface 112 and the supporting surface 122.

Specifically, the host device 110 includes a first connection port and the base device 120 includes a second connection port. The host device 110 is mounted to the base device 120 by coupling the first connection port to the second connection port. The first connection port of the host device 110 is disposed on the bottom surface 112, and the second connection port of the base device 120 is disposed on the supporting surface 122. The first connection port has a first region 114 and the second connection port has a second region 124. The first region 114 is, for example, a sector region having an angle θ, and has a plurality of arc-shaped or ring-shaped wires or metal pads CW on the upper surface thereof. Second region 124 also has a plurality of conductive wires or metal pads CW that are positioned to correspond to the conductive wires or metal pads CW in first region 114. In addition, the first connection port further includes a first magnetic connection portion 116, the second connection port further includes a second magnetic connection portion 126, and the first magnetic connection portion 116 and the second magnetic connection portion 126 have a magnetic attraction effect therebetween for fixing the relative positions of the first region 114 and the second region 124.

In the embodiment of fig. 5A, the positions of the first magnetic connecting portion 116 and the second magnetic connecting portion 126 are staggered, and the positions of the first region 114 and the second region 124 are staggered, that is, the metal wires CW in the first region 114 are not connected to the metal wires CW in the second region 124, so that the host device 110 is not electrically connected to the base device 120, and the host device 110 or the base device 120 is not powered on.

The supporting surface 122 in fig. 5A is rotated relative to the bottom surface 112 by an angle, so that the host device 110 and the base device 120 are changed from the condition of fig. 5A to the condition of fig. 5B. In the embodiment of fig. 5B, the first magnetic connection 116 and the second magnetic connection 126 magnetically attract to fix the position of the first region 114 and the second region 124, and the first region 114 and the second region 124 at least partially overlap. The metal wires CW on the first area 114 and the second area 124 are connected to electrically connect the host device 110 and the base device 120. When the host device 110 is electrically connected to the base device 120, the host device 110 or the base device 120 may be set to enter the power-on state. Conversely, when the user rotates the host device 110 from the state shown in fig. 5B to the state shown in fig. 5A, the first area 114 is staggered from the second area 124, the host device 110 is electrically disconnected from the base device 120, and the host device 110 or the base device 120 is powered off.

The details of the implementation of the split mobile intelligent system are further described below.

Fig. 6 is a block diagram of a separated mobile intelligent system according to an embodiment of the invention, and fig. 7 is a flowchart of an operation method of the separated mobile intelligent system according to another embodiment of the invention. The method of operation of fig. 7 is applicable to the embodiment of fig. 6, and the embodiment of fig. 6 is also applicable to the embodiment of fig. 1B. The following describes an implementation of a separate mobile intelligent system and an operation method thereof according to another embodiment with reference to the components of fig. 6.

Referring to fig. 6, the host device 200 has a voice recognition function and is suitable for various base devices. The user can give commands to the host device 200 by voice to control various base devices.

The host device 200 includes a first control device 210, a microphone 220, a first connection port 230, a first memory 240, and a wireless communication interface 250. The base device 300 includes a second control device 310, a power supply device 320, a second connection port 330 and a second memory 340. The first control device 210 is coupled to the microphone 220, the first connection port 230, the first memory 240 and the wireless communication interface 250. The second control device 310 is coupled to the power device 320, the second connection port 330 and the second memory 340.

Specifically, the first control Device 210 or the second control Device 310 is, for example, a Central Processing Unit (CPU), or other Programmable microprocessors (microprocessors), digital Signal Processors (DSPs), programmable controllers, application Specific Integrated Circuits (ASICs), programmable Logic Devices (PLDs), or other similar devices, which is not limited by the invention.

The first memory 240 and the second memory 340 are any type of fixed or removable Random Access Memory (RAM), read-only memory (ROM), flash memory (flash memory), hard disk or other similar devices, integrated circuits, and combinations thereof. The first memory 240 or the second memory 340 records a plurality of instructions or functional modules that can be executed by the first control device 210 or the second control device 310, and the first control device 210 or the second control device 310 can execute the instructions to perform the above-mentioned functions.

The microphone 220 may include at least one microphone, and the microphone 220 may also be a microphone array to increase the sound-collecting effect of the host device 200.

The wireless communication interface 250 is, for example, a wireless network card supporting wireless communication standards such as Institute of Electrical and Electronics Engineers (IEEE) 802.11n/b/g, or a network card supporting wired network connection such as Ethernet (Ethernet), and can provide wired or wireless connection with other devices on the network, such as a cloud server CLS.

In step S710, the host device 200 is electrically connected to the base device 300. The second connection port 330 is coupled to the first connection port 230 such that the host device 200 is electrically connected to the base device 300. In this embodiment, the host device 200 may not include a battery, and the base device 300 supplies power to the host device 200 through the second connection port 330. When the host device 200 is detached from the base device 300, the host device 200 is turned off, and when the host device 200 is attached to the base device 300, the host device 200 is powered on from the base device 300.

In another embodiment, the host device 200 may include a battery, such as the battery 260 of fig. 9, and the host device 200 may be powered by the battery 260 and start by itself, and the invention is not limited to whether the host device 200 includes a battery.

Next, in step S720, the first control device 210 of the host device 200 receives the product identification code of the base device 300 from the base device 300 to determine the product type of the base device 300. The second memory 340 stores the product identification code of the base device 300, and the first memory 240 stores a lookup table LT, wherein the lookup table LT records a plurality of reference identification codes and a plurality of corresponding categories. After the host device 200 is electrically connected to the base device 300, the base device 300 transmits the product identification code to the first control device 210, and the first control device 210 compares the product identification code of the base device 300 with the look-up table LT to determine the type of the base device 300. For example, the first control device 210 can determine whether the connected base device 300 is a speaker or a lighting device according to the product identification code.

The first memory 240 also stores a plurality of product driving signals. For example, the first memory 240 stores a driving signal for driving a speaker, a driving signal for driving a lighting device, or a driving signal for driving other electronic products. In step S730, the first control device 210 may select a corresponding product driving signal from the product driving signals according to the product identification code of the base device 300. In other words, after the base device 300 is electrically connected to the host device 200, the host device 200 determines what type of product the base device 300 is based on the product id of the base device 300, and selects the corresponding product driving signal according to the product type. Accordingly, the host device 200 can be connected to different types of base devices 300 and select an appropriate driving signal to drive the base device 300 accordingly.

In step S740, the microphone 220 may receive a voice command S of the user U to generate a voice signal. In step S750, the first control device 210 transmits the voice signal to the cloud server CLS through the wireless communication interface 250. In this embodiment, in order to reduce the operation burden of the first control device 210, the host device 200 may further upload the voice signal to the cloud server CLS, and the cloud server CLS performs a recognition or matching operation on the voice signal, such as performing semantic analysis, and recognizing the dialog content of the user U to generate a corresponding control command. In an embodiment, the first memory 240 further stores a voice processing module VM, and the first control device 210 executes the voice processing module VM to analyze and process the voice signal. The voice signal transmitted to the cloud server CLS may be a signal processed by the voice processing module VM or a signal not processed by the voice processing module VM.

In step S760, the cloud server CLS may generate a control signal according to the voice signal and transmit the control signal to the host device 200 through the network. Next, in step S770, the base device 300 receives the control signal through the host device 200, and then performs step S780, and the base device 300 performs the corresponding operation mode according to the control signal.

An embodiment will be described below. The base device 300 is a speaker, and after the host device 200 is connected to the base device 300, it is determined that the base device 300 is used for playing music according to the product identification code. In the present embodiment, the user U speaks the audio command S with the content "play Wang Xiaoming song", and the microphone 220 receives the audio command S to generate a voice signal. The host device 200 uploads the voice signal to the cloud server CLS through the wireless communication interface 250, and the cloud server CLS performs voice recognition processing. The host device 200 receives at least one sound source signal from the cloud server CLS according to the voice signal, so that the speaker plays the sound source signal. Specifically, the cloud server CLS may recognize that the voice command S is to play a song that the singer has named "Wang Xiaoming" and generate a control signal that is interpretable by the hardware device accordingly. The cloud server CLS may also connect to the cloud music database to obtain the audio source signal of "Wang Xiaoming". The host device 200 downloads the audio signal and the control signal for "Wang Xiaoming" from the cloud server CLS via the network. The base device 300 receives the control signal and the audio signal, wherein the second control device 310 can make the base device 300 execute the corresponding operation mode according to the control signal, that is, make the base device 300 play the song "Wang Xiaoming".

In another embodiment, the host device 200 may not need to download the audio source signal from the network. The first memory 240 may further store a plurality of audio signals, and the host device 200 may select one of the audio signals according to the voice signal and cause the base device 300 to play the selected audio signal.

Specifically, in the embodiment, since the host device 200 does not have a battery, the host device 200 cannot be started when the host device 200 is not installed in the base device 300, and in some embodiments, the second control device 310 operates according to the control signal, and if no control signal is provided by the host device 200, the base device 300 cannot operate by itself. In other words, the host device 200 and the base device 300 of the separated mobile intelligent system in these embodiments need to be combined, the separated mobile intelligent system can only operate, and after being separated, the base device 300 cannot execute the operation mode. For example, when the base device 300 is a speaker, the base device 300 without the host device 200 is left with only the speaker body, and cannot actively emit sound. However, in other embodiments, the base device 300 without the host device 200 can still execute a part of the operation mode, which is not limited by the invention.

Fig. 9 is a block diagram of a separated mobile intelligent system according to another embodiment of the invention. Referring to fig. 9, the separated mobile intelligent system of fig. 9 is similar to the embodiment of fig. 6, except that the embodiment of fig. 9 has more batteries 260 but is not connected to the cloud server CLS. The battery 260 is used to provide power for the operation of the host device 200. It is specifically noted that the battery 260 is not required, and in other embodiments, the detached mobile intelligent system may not need the battery 260, and the host device 200 is powered by the power device 320 of the base device 300 through the first connection port 230 and the second connection port 330. In addition, the split mobile intelligent system of fig. 9 can also be regarded as an operation example of the embodiment of fig. 6 when no network is connected. The detached mobile intelligent system of fig. 9 can generate the control signal according to the voice command S without connecting the cloud server CLS.

In the present embodiment, the user U speaks the audio command S with the content "pause playing", and the microphone 220 receives the audio command S to generate a voice signal. The first control device 210 may execute the voice processing module VM to analyze and process the voice signal. For example, the first memory 240 stores a plurality of reference voice signals, and the first control device 210 can compare the voice signals with the reference voice signals to recognize that the voice command S is for pausing the base device 300. The first control device 210 generates a control command according to the voice signal and transmits the control command to the second control device 310. The second control device 310 causes the base device 300 to pause playing music according to the control command.

In brief, in one embodiment, the host device 110 receives the voice command S from the user U to generate a voice signal, and the host device 110 may upload the voice signal to the cloud server CLS, and the cloud server CLS may recognize the voice signal to provide the control command. The host device 110 transmits the control command from the cloud server CLS to the second control device 310 of the base device 300, so that the base device 300 executes the operation mode desired by the user U according to the control command.

In another embodiment, when the base unit 300 is a media player (such as a speaker or a display), the base unit 300 can also receive multimedia signals such as audio signals or video signals from the cloud server CLS through the host device 110 for playing according to the control signal. In another embodiment, the first memory 240 stores audio signals, video signals, or the like. The host device 110 can provide the audio signal to the base device 300 according to the control command from the cloud server CLS. In another embodiment, the host device 110 may not generate the control command according to the voice signal through the cloud server CLS.

FIG. 8 is a diagram of a host device and a plurality of different types of base devices according to an embodiment of the invention. As described above, the host device 110 of the present embodiment can be adapted to a plurality of different types of base devices 820. The base device 820 may be a speaker or a lighting device, and may also be various intelligent appliances, for example, the base device 820 shown in fig. 8 may be an electronic exhibit such as a washing machine, a refrigerator, a coffee machine, a microwave oven, an induction cooker, a television, and the like, and the invention is not limited thereto. Each base device 820 includes a bearing surface 122 for mounting the host 110. The host device 110 is mounted on the carrying surface 122 to connect with the base device 820. The operating modes of the base device 820 include a power-on mode, a standby mode, a wake-up mode, a power-off mode, a home appliance function control mode, a lighting mode, a music playing mode, and the like.

The host device 110 may control the base device 820 to enter a boot mode, a standby mode, an awake mode or a power-off mode, and the host device 110 may also control the base device 820 according to the type of the base device 820. Specifically, when the base device 820 is a speaker, the host device 110 may control the base device 820 to perform a music play mode; when the base device 820 is a lighting device, the host device 110 can control the base device 820 to perform a lighting mode; when the base device 820 is a microwave oven, the home appliance function control mode is, for example, the base device 820 performs thawing, heating, or the like; when the base unit 820 is a refrigerator, the home appliance function control mode is, for example, adjusting the refrigerating temperature of the base unit 820, or the like; when the base unit 820 is a coffee maker, the home appliance function control mode is, for example, the base unit 820 selects to cook cappuccino or latte, etc. flavored coffee, and so on. The present invention does not limit the product type of the base device 820 nor the range of the home appliance function control mode of the base device 820.

It is noted that, in some embodiments, when the base device 820 is not installed with the host device 110, the user cannot control the base device 820 by voice through the host device 110, but can control the base device 820 through the human-machine interface of the base device 820, for example, by touching the keyboard. In short, in some embodiments, the base device 820 is not equipped with the host device 110 and can still perform at least part of the operation mode, and in some other embodiments, the base device 820 is not equipped with the host device 110 and thus the host device 110 can be regarded as the start key of the base device 820.

In other embodiments, the host device 110 may be equipped with other sensing devices, such as motion sensing devices. The host device 110 can also generate the control signal by the gesture of the user. The invention does not limit the intelligent interaction mode between the host device and the user.

In summary, the separated mobile intelligent system, the operating method thereof and the base device according to the embodiments of the invention can physically separate the host device from the base device, and the host device can be combined with at least one or more base devices. The user can use the same host device to match with different base devices. The plurality of base units can be used commonly with the same host unit, so that a user can select to mount the host unit on a desired base unit. To the base device that installs the host computer device, the user can carry out intelligent operation to the base device through the host computer device, promotes man-machine control and experiences by this. Through detachable host computer device, the base device of selecting can have intelligent operation function, and when base device damaged, the user need not replace whole intelligent system in addition, and can replace the base device and reduce cost of maintenance. When the user has different requirements, the base device can be replaced to meet the requirements of the user, so that the application flexibility of the user on the intelligent system is greatly improved.

Although the present invention has been described with reference to the above embodiments, it should be understood that various changes and modifications can be made therein by those skilled in the art without departing from the spirit and scope of the invention.

Claims (22)

1. A split mobile intelligence system, comprising:

a host device, comprising:

a first connection port;

a microphone for receiving a voice command to generate a voice signal;

the first control device is coupled with the first connecting port and the microphone and used for providing a control signal according to the voice signal; and

the first memory is used for storing a lookup table, and the lookup table records a plurality of reference identification codes and a plurality of corresponding categories;

at least one base device, the host device being removably mounted to the at least one base device, wherein the at least one base device has a plurality of operating modes and comprises:

a second connection port coupled to the first connection port and receiving the control signal from the host device; and

a second memory for storing the product identification code of the at least one base device;

wherein the first control device compares the product identification code with the lookup table to determine the category of the at least one base device,

and the at least one base device connected with the host device executes the corresponding operation mode according to the control signal.

2. The separated mobile intelligent system according to claim 1, wherein the first memory stores a plurality of product driving signals, and the first control device selects one of the plurality of product driving signals to drive the at least one base device according to the product identification code.

3. The split mobile intelligent system according to claim 1, wherein the host device further comprises:

the wireless communication interface is coupled with the first control device and the cloud server, and is characterized in that the first control device transmits the voice signal to the cloud server through the wireless communication interface, the cloud server generates the control signal according to the voice signal, and the host device receives the control signal through the wireless communication interface.

4. The detached mobile intelligent system of claim 3, wherein the base is a speaker, and the host device further receives an audio signal from the cloud server according to the voice signal to enable the speaker to play the audio signal.

5. The detached mobile intelligent system of claim 1, wherein the host device comprises a bottom surface connected to the at least one base device, the at least one base device having a carrying surface for connecting to the bottom surface, wherein the host device determines whether to boot up according to a relative rotation angle between the bottom surface and the carrying surface.

6. The detached mobile intelligent system of claim 5, wherein the first connection port is configured on the bottom surface and has a first area, and the second connection port is configured on the bearing surface and has a second area, wherein the host device is powered on when the first area and the second area at least partially overlap.

7. The detached mobile intelligent system of claim 1, wherein the at least one base unit further comprises a second control unit, the second control unit being coupled to the second connection port and causing the at least one base unit to perform the corresponding operation mode according to the control signal.

8. The detached mobile intelligent system of claim 1, wherein the at least one base unit further comprises a power supply unit for providing power to the host unit through the second connection port.

9. The separated mobile intelligent system according to claim 1, wherein the base is a speaker, and the host device further comprises a first memory for storing a plurality of audio signals, and the host device further selects one of the plurality of audio signals according to the voice signal and causes the speaker to play the audio signal.

10. The detached mobile intelligence system of claim 1 wherein the plurality of operating modes includes a start-up mode, a standby mode, a wake-up mode, a power-off mode, a home appliance function control mode, a lighting mode, or a music play mode.

11. A method of operating a split mobile intelligent system, wherein the split mobile intelligent system includes a host device and at least one base device, wherein the at least one base device has a plurality of operating modes, the method comprising:

removably mounting said host device to said at least one base device;

comparing, by the host device, a product identifier of the at least one base device connected to the host device with a lookup table to determine a category of the at least one base device, wherein the lookup table records a plurality of reference identifiers and a plurality of corresponding categories;

receiving, by the host device, a voice command to generate a voice signal;

providing, by the host device, a control signal according to the voice signal; and

and executing the corresponding operation mode by the at least one base device according to the control signal.

12. The method of operation of claim 11, further comprising:

one of a plurality of product driving signals is selected to drive the at least one base device according to the product identification code.

13. The method of claim 11, wherein the step of providing the control signal by the host device in accordance with the voice signal comprises:

and transmitting the voice signal from the host device to a cloud server through wireless communication, and generating the control signal by the cloud server according to the voice signal, wherein the host device receives the control signal through the wireless communication.

14. The method of claim 13, wherein the base is a speaker, and the host device further receives an audio signal from the cloud server according to the voice signal to enable the speaker to play the audio signal.

15. The method of operation of claim 11, further comprising:

the host device is powered by the at least one base device.

16. The method of claim 11, wherein the base is a speaker, and wherein the host device selects one of a plurality of audio signals according to the voice signal and causes the speaker to play the audio signal, and wherein the host device further comprises a first memory for storing the audio signals.

17. The method of claim 11, wherein the plurality of operating modes comprises a power-on mode, a standby mode, a wake-up mode, a power-off mode, a home appliance function control mode, a lighting mode, or a music playing mode.

18. A base device on which a host device is detachably mounted, the base device comprising:

a connection port for connecting the host device;

a memory to store a product identification code of the base device; and

a control device coupled to the connection port and configured to control the base device to execute one of a plurality of operation modes,

wherein the control device receives a control signal from the host device through the connection port, the control signal being generated by the host device according to a voice command,

wherein the host device receives the product identification code through the connection port to determine the category of the base device,

and the base device executes the corresponding operation mode according to the control signal.

19. The dock device of claim 18, wherein the host device selects one of a plurality of product driver signals according to the product identification code, wherein the selected product driver signal causes the host device to drive the dock device.

20. The base unit of claim 18, wherein the base is a speaker and receives an audio signal from the host unit for playing the audio signal.

21. The base unit of claim 18, further comprising a power supply unit for providing power to the host unit through the connection port.

22. The base unit of claim 18, wherein the plurality of operating modes includes a power-on mode, a standby mode, a wake-up mode, a power-off mode, a home appliance function control mode, a lighting mode, or a music playing mode.

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