CN212302476U - System level chip and intelligent wearing equipment - Google Patents

Abstract

The utility model provides a system-level chip and intelligent wearable equipment, wherein the system-level chip comprises a power management chip, a RAM, a main control subsystem, an auxiliary control subsystem and a plurality of functional subsystems; the main control subsystem, the auxiliary control subsystem and the functional subsystem all comprise an MCU; the main control subsystem, the auxiliary control subsystem and the functional subsystem are all connected with the RAM through buses; the power management chip is used for supplying power to the RAM, the main control subsystem, the auxiliary control subsystem and the functional subsystems. The utility model discloses a with power management chip, RAM, master control subsystem, vice accuse subsystem and a plurality of functional subsystem integration in a system level chip, compare with the function that utilizes many chips to realize the same, not only reduced consumption and cost, effectively reduced the required space of PCB cloth board moreover to for intelligent wearing equipment provides abundant function application, low-power consumption, not receive PCB overall arrangement restriction and low-cost solution.

Description

System level chip and intelligent wearing equipment

Technical Field

The utility model relates to a Chip technology field, in particular to System level Chip (System on Chip, SoC) and intelligent wearing equipment.

Background

The intelligent wearing equipment is a general name for applying wearing technology to intelligently design daily wearing and develop wearable equipment, such as watches, bracelets, glasses, clothes and the like. The smart watch is the most widely applied device type in the smart wearable device.

An important functional feature for smartwatches is long standby and long endurance. Due to the physical size constraints, all the electronic components must be integrated into a dial with a diameter of around 40mm, which causes limitations in the PCB layout and in the battery capacity if a smartwatch is desired to integrate more functions. In addition, the smart watch often cannot be loaded with a battery with a large capacity, and due to the convenience of use of wearing the smart watch, a user often expects that the smart watch can be charged once in a week or even two weeks.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a system level chip and intelligent wearing equipment in order to overcome the defect that intelligent wearing equipment can't compromise low-power consumption, multi-functional and PCB overall arrangement among the prior art.

The utility model discloses an above-mentioned technical problem is solved through following technical scheme:

a first aspect of the present invention provides a system-level chip, which includes a power management chip, a RAM (Random Access Memory), a main control subsystem, a sub-control subsystem, and a plurality of functional subsystems; wherein, different functional subsystems are used for realizing different functions;

the main control subsystem, the secondary control subsystem and the functional subsystem all comprise an MCU (micro controller Unit);

the main control subsystem, the auxiliary control subsystem and the functional subsystem are all connected with the RAM through buses;

the main control subsystem and the auxiliary control subsystem are respectively connected with the functional subsystem through interrupt lines, and are used for responding to interrupt signals sent by the functional subsystem in a time-sharing manner;

the power management chip is used for providing power for the RAM, the main control subsystem, the auxiliary control subsystem and the functional subsystems.

Preferably, the RAM includes an SRAM (Static Random-Access Memory) and a DRAM (Dynamic Random-Access Memory).

Preferably, the SRAM, the main control subsystem, the sub-control subsystem, and the functional subsystem are integrated in one chip, and are packaged with the DRAM and the power management chip by SIP.

Preferably, the System-on-chip further includes a Read-Only Memory (ROM), and the ROM is packaged with a chip integrating the SRAM, the main control subsystem, the sub-control subsystem, and the functional subsystem, the DRAM, and the power management chip by a SIP (System In a Package).

Preferably, the system-on-chip further includes a display subsystem for acquiring image data from the DRAM, and the display subsystem is integrated with the SRAM, the main control subsystem, the sub-control subsystem, and the functional subsystem in the same chip.

Preferably, the main control subsystem, the secondary control subsystem and the functional subsystem all have independent power domains.

Preferably, an RTOS (Real Time Operating System) Operating System is embedded in the System on chip.

Preferably, the functional subsystems include a plurality of: a wireless Modem subsystem, a Bluetooth subsystem, a Wi-Fi subsystem, a GPS (Global Positioning System) subsystem and a camera subsystem.

A second aspect of the utility model provides an intelligence wearing equipment, include touch-sensitive screen, a plurality of sensor and as the first aspect the system level chip, the touch-sensitive screen with the sensor respectively with the system level chip electricity is connected.

Preferably, the intelligent wearable device is a smart watch.

The utility model discloses an actively advance the effect and lie in: the utility model discloses a with power management chip, RAM, master control subsystem, vice accuse subsystem and a plurality of functional subsystem integration in a system level chip, utilize many chips to realize the same function among the prior art and compare, not only reduced consumption and cost, effectively reduced the required space of PCB cloth board moreover to for intelligent wearing equipment provides abundant function application, low-power consumption, not receive PCB overall arrangement restriction and low-cost solution.

In addition, for further reducing the power consumption, the utility model provides a system level chip adopts the RTOS operating system of the MCU of light-weight and ultra-low power consumption.

Drawings

Fig. 1 is a block diagram of a system-on-chip according to embodiment 1 of the present invention.

Fig. 2 is a schematic diagram of a connection relationship between each subsystem and the RAM in embodiment 1 of the present invention.

Fig. 3 is a block diagram of another system-on-chip according to embodiment 1 of the present invention.

Fig. 4 is a block diagram of the intelligent wearable device provided in embodiment 2 of the present invention.

Detailed Description

The present invention will be more clearly and completely described below with reference to the accompanying drawings.

Example 1

The present embodiment provides a system-level chip, as shown in fig. 1, including a power management chip, a RAM, a main control subsystem, a sub-control subsystem, and a plurality of functional subsystems.

The main control subsystem, the auxiliary control subsystem and the functional subsystem all comprise MCUs. As shown in fig. 1, the main control subsystem includes MCU-main control, the sub-control subsystem includes MCU-sub control, the functional subsystem 1 includes MCU-1, the functional subsystem 2 includes MCU-2, and the functional subsystem N includes MCU-N. Each subsystem can be switched between a working mode and a sleep mode, so that the purposes of low power consumption and power saving are achieved.

The MCU is also called a Single Chip Microcomputer (MCU) or a Single Chip Microcomputer (MCU), which properly reduces the frequency and specification of the cpu, and integrates the peripheral interfaces such as memory, counter, USB, a/D conversion, UART, PLC, DMA, etc. on a Single Chip to form a Chip-level computer for different applications. The MCU in this embodiment may be a processor of RISC architecture such as ARM Cortex-M/R series, MIPS (Microprocessor without Interlocked Pipelined microprocessors), RISC-V, MCS8051, and the like.

In some examples, the master subsystem, the secondary subsystem, and the MCU in each of the functional subsystems are the same, such as processors in the ARM Cortex-M family. In other examples, the MCU in the main control subsystem, the sub-control subsystem, and each functional subsystem is different, and different MCUs may be specifically selected according to the functions implemented by the subsystems, which is not limited specifically.

The main control subsystem, the auxiliary control subsystem and the function subsystem are all connected with the RAM through buses, the main control subsystem and the auxiliary control subsystem are respectively connected with the function subsystem through interrupt lines, and the main control subsystem and the auxiliary control subsystem are used for responding to interrupt signals sent by the function subsystem in a time-sharing mode, so that transmission of message streams and data streams among the subsystems is achieved. In a specific example, the main control subsystem, the sub-control subsystem and the functional subsystem implement the memory space of the shared RAM through a unified memory access matrix.

In a specific implementation, if the main control subsystem is in the working mode, the main control subsystem responds to the interrupt signals sent by the functional subsystems, and the auxiliary control subsystem is prohibited from responding to the interrupt signals sent by the functional subsystems. And if the main control subsystem is in a sleep mode or is powered off, the auxiliary control subsystem responds to the interrupt signals sent by the functional subsystems and forbids the main control subsystem to respond to the interrupt signals sent by the functional subsystems.

In an optional implementation manner, the main control subsystem and the sub-control subsystem are connected by an interrupt line, and the main control subsystem can respond to an interrupt signal sent by the sub-control subsystem no matter the main control subsystem is in a working mode or a sleep mode.

In one specific example, the main control subsystem can complete complex multimedia system applications, can completely respond to user operations, and can even execute complex user applications. The secondary control subsystem is mainly used for AOD (Always On Display, information screen Display technology) Display when the main control subsystem is in sleep and controlling various external sensors. Therefore, the master frequency, the memory consumption and the power consumption of the MCU in the master control subsystem are higher than those of the MCU in the auxiliary control subsystem. Each functional subsystem respectively realizes independent functions, is turned on to work only when needed, and enters a dormant state when not needed, even needs to be powered off, so that the power consumption is thoroughly saved.

The power management chip is used for providing power for the RAM, the main control subsystem, the auxiliary control subsystem and the functional subsystems. The power management chip in this embodiment can output a plurality of different voltages, thereby providing power to different subsystems. In one specific example, the power management chip includes a PWM charger, a multi-way DC-DC converter (Buck DC-DC), and a multi-way linear regulator (LDO).

Wherein different functional subsystems are used to implement different functions. The functional subsystems in this embodiment may include a wireless Modem subsystem, a bluetooth subsystem, a Wi-Fi subsystem, a GPS subsystem, a camera subsystem, and the like.

The wireless Modem subsystem comprises a wireless Modem and is used for realizing functions of answering/dialing a call, moving a data network and the like. The wireless Modem generally comprises baseband processing, modulation and demodulation, signal amplification and filtering, equalization, and the like, and is used for wirelessly transmitting digital signals of data communication on an analog channel with limited bandwidth. The Bluetooth subsystem is used for realizing the function of wireless communication with external equipment in short distance. The Wi-Fi subsystem is used for realizing a wireless internet function. The GPS subsystem is used for realizing the functions of real-time positioning and navigation in the global range. The camera subsystem includes a camera for capturing still images or video.

In an alternative embodiment, the RAM includes SRAM and DRAM. In some examples, the DRAM may be LPDDR2, LPDDR3, or the like. The LPDDR (low Power Double Data Rate SDRAM) is one of DDR SDRAM (Double Data Rate SDRAM) and is a communication standard established for low Power consumption memory, LPDDR2 is a second generation low Power consumption memory technology, and LPDDR3 is a third generation low Power consumption memory technology.

Fig. 2 is a schematic diagram for illustrating a connection relationship between each subsystem and the RAM. As shown in fig. 2, the main control subsystem, the sub-control subsystem and the functional subsystem are all connected with the SRAM and the DRAM through buses, and the main control subsystem is connected with the sub-control subsystem and the functional subsystems through interrupt lines.

In an optional implementation manner, the SRAM, the main control subsystem, the sub-control subsystem, and the plurality of functional subsystems are integrated into one chip, and are packaged with the DRAM and the power management chip through an SIP. The SIP package is an electronic device package scheme, and integrates a plurality of functional chips, including functional chips such as a processor, a memory and the like, into one package, thereby realizing a basically complete function.

In this embodiment, since the SRAM is integrated with the main control subsystem, the sub-control subsystem, and the plurality of functional subsystems in one chip, the SRAM may also be referred to as an on-chip SRAM, and the DRAM may also be referred to as an off-chip DRAM. The on-chip SRAM has the characteristics of low power consumption, high speed, small memory capacity and high price. Off-chip DRAM has the characteristics of large memory capacity, but high power consumption. In order to avoid excessive use of the off-chip DRAM with high power consumption, the present embodiment classifies message streams and data streams transmitted between subsystems, and realizes transmission of the message streams and the data streams by sharing the spaces of the on-chip SRAM and the off-chip DRAM, thereby reducing power consumption of the system-on-chip.

In an alternative embodiment, as shown in fig. 3, the system-on-chip further includes a ROM, and the ROM is packaged with a chip integrating the SRAM, the main control subsystem, the sub-control subsystem, and the functional subsystem, the DRAM, and the power management chip by an SIP. The ROM in this embodiment includes, but is not limited to, an EMMC, NAND Flash, NOR Flash, and the like.

In a specific example, an ePoP packaging process is first adopted, the ROM and the DRAM are stacked on a Chip integrating the SRAM, the main control subsystem, the sub-control subsystem, and all the functional subsystems, and then an FCCSP (Chip Scale Package) packaging process is adopted to integrate the ROM and the DRAM with a power management Chip, thereby obtaining a system-on-Chip of the present embodiment.

In an optional embodiment, the system-on-chip further includes a display subsystem, configured to obtain image data from the DRAM, where the display subsystem, the SRAM, the main control subsystem, the sub-control subsystem, and the function subsystem are integrated in a same chip. The main control subsystem or the auxiliary control subsystem is used for writing image data to be displayed into the DRAM, and the display subsystem reads the image data from the DRAM, processes the image data and outputs the image data to an external display for displaying.

In this embodiment, the display subsystem does not include an MCU.

In an optional implementation manner, the main control subsystem, the secondary control subsystem, and the functional subsystem all have independent power domains, that is, each subsystem may be powered on or powered off independently without mutual influence. In one specific example, the master control subsystem outputs a preset level signal to the power domain of the functional subsystem to control the power-on of the functional subsystem. In another specific example, the secondary control subsystem outputs a preset level signal to the power domain of the primary control subsystem to control the power-up of the primary control subsystem.

In an alternative embodiment, the system-on-chip has an RTOS operating system embedded therein. Unlike Android, Windows, IOS and other intelligent operating systems, the RTOS operating system is a lightweight microkernel operating system, can be applied to an MCU controller, provides microsecond response speed, and belongs to an operating system with ultra-low power consumption. In one example, each MCU in the system-on-chip has an RTOS operating system embedded therein. In another example, an RTOS operating system is embedded in a portion of the MCUs in the system-on-chip. The design can be specifically carried out according to the resources and the like required by realizing different functions of each subsystem.

This embodiment is through integrating power management chip, RAM, master control subsystem, vice control subsystem and a plurality of functional subsystem in a system level chip, compares with utilizing many chips to realize the same function among the prior art, has not only reduced consumption and cost, has effectively reduced the required space of PCB cloth board moreover to for intelligent wearing equipment provides abundant function application, low-power consumption, not restricted and the low-cost solution of PCB overall arrangement.

Example 2

The embodiment provides an intelligent wearable device, as shown in fig. 4, including a touch screen, a plurality of sensors and the system-on-chip of embodiment 1, the touch screen and the sensors are respectively electrically connected with the system-on-chip. In the embodiment, the user can operate the content displayed by the intelligent wearable device through the touch screen, and the intelligent wearable device makes different responses based on different operations of the user.

Due to the use of the system-on-chip provided by embodiment 1, the intelligent wearable device provided by the embodiment has the advantages of rich functional applications, low power consumption and low cost.

In alternative embodiments, the sensor includes a heart rate sensor, an acceleration sensor, a gyroscope sensor, and the like. The auxiliary control subsystem in the system-on-chip is used for realizing the function of a Sensor Hub (Sensor control center), and specifically comprises the steps of carrying out real-time control on the Sensor, so that the function of reducing power consumption is achieved, fusing data of sensors of different types, realizing the function which can be realized only by combining data of various sensors and the like.

In an optional embodiment, the smart wearable device is a smart watch, such as an adult smart watch, a child smart watch, an elderly smart watch, and the like.

In some optional embodiments, the smart wearable device may further be a smart band, smart glasses, smart clothes, or the like.

Although specific embodiments of the present invention have been described above, it will be understood by those skilled in the art that this is by way of example only and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and the principles of the present invention, and these changes and modifications are all within the scope of the present invention.

Claims (10)

1. A system-level chip is characterized by comprising a power management chip, a RAM, a main control subsystem, a secondary control subsystem and a plurality of functional subsystems; wherein, different functional subsystems are used for realizing different functions;

the main control subsystem, the auxiliary control subsystem and the functional subsystem all comprise MCUs;

the main control subsystem, the auxiliary control subsystem and the functional subsystem are all connected with the RAM through buses;

the main control subsystem and the auxiliary control subsystem are respectively connected with the functional subsystem through interrupt lines, and are used for responding to interrupt signals sent by the functional subsystem in a time-sharing manner;

the power management chip is used for providing power for the RAM, the main control subsystem, the auxiliary control subsystem and the functional subsystems.

2. The system-on-chip of claim 1, in which the RAM comprises SRAM and DRAM.

3. The system-on-chip of claim 2, wherein the SRAM, the master control subsystem, the secondary control subsystem, and the functional subsystem are integrated in one chip and packaged with the DRAM and the power management chip via SIP.

4. The system-on-chip of claim 3 further comprising a ROM, the ROM packaged with a chip integrating the SRAM, the master subsystem, the secondary subsystem, and the functional subsystem, the DRAM, and the power management chip via SIP.

5. The system-on-chip of claim 3 further comprising a display subsystem for obtaining image data from the DRAM, the display subsystem integrated within the same chip as the SRAM, the master subsystem, the secondary control subsystem, and the functional subsystem.

6. The system-on-chip of claim 1, wherein the master control subsystem, the secondary control subsystem, and the functional subsystem each have independent power domains.

7. The system-on-chip of claim 1, wherein the system-on-chip has an RTOS operating system embedded therein.

8. The system-on-chip of any one of claims 1-7, wherein the functional subsystem comprises a plurality of: the system comprises a wireless Modem subsystem, a Bluetooth subsystem, a Wi-Fi subsystem, a GPS subsystem and a camera subsystem.

9. An intelligent wearable device, comprising a touch screen, a plurality of sensors and the system-on-chip of any of claims 1-8, wherein the touch screen and the sensors are electrically connected to the system-on-chip, respectively.

10. The smart wearable device of claim 9, wherein the smart wearable device is a smart watch.

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