JP2017049873A - Host apparatus, slave device and removable system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a host apparatus etc. capable of maintaining compatibility of interface and ensuring safe use even when a new low voltage interface is introduced.SOLUTION: A removable system is constituted of a host apparatus and a slave device attachable/detachable to the host apparatus. When the slave device detects a power source, a clock signal and a 0 signal on a first signal line from a connected host apparatus, 0 is transmitted from a second signal line. When the host apparatus detects 0 on the second signal line, the first signal line is suspended from being driven. After checking that the second signal line is 1, an initialization is executed.SELECTED DRAWING: Figure 8

Description

  The present disclosure relates to a host device and a slave device that can be connected to each other, and a removable system including the host device and the slave device.

  In recent years, slave devices such as a card-shaped SD card and a memory stick, which have a large-capacity non-volatile storage element such as a flash memory and can process data at high speed, have spread in the market. Such slave devices are used in personal computers, smartphones, digital cameras, audio players, car navigation systems, and the like, which are host devices that can use the slave devices.

  For example, Patent Document 1 discloses a technique for selecting an operating voltage from a plurality of interface voltages in a communication system using a host device and a slave device.

  Patent Document 2 uses an electronic device (slave device) depending on whether the power is ON or OFF and whether a specific signal line is at a high level or a low level. A technique for determining an interface circuit to perform is disclosed.

International Publication No. 2009/107400 JP 2003-337639 A

  In a communication system using a host device and a slave device, it is effective to reduce the interface voltage in order to improve the interface processing speed. Furthermore, with the recent miniaturization of semiconductor processes, there is an increasing demand for introducing a semiconductor device limited to a lower interface voltage particularly in a host device. On the other hand, there is also a demand for maintaining interface compatibility so that existing interfaces that are popular in the market can be used continuously. That is, there is a demand for the slave device and the shape of the slot to be mounted on the host to connect the slave device to the host device, the position of the terminal, the size, etc. remain the same as the conventional one.

  When trying to satisfy these simultaneously, there is a possibility that a slave device with a new interface corresponding to an interface voltage relatively lower than that of the existing interface is erroneously attached to a host device with an existing interface. Similarly, a slave device with an existing interface may be erroneously attached to a host device with a new interface corresponding to an interface voltage that is relatively lower than the existing one. Then, there is a possibility that the new interface-side device is destroyed by the relatively high interface voltage of the existing interface-side device.

  The present disclosure has been made in view of the above problems, and maintains a compatible interface, and at the same time, even if the interface voltage of a single-ended method is reduced, a host device, a slave device, And a removable system.

  The present disclosure is a host device that can be connected to a slave device through a plurality of interfaces having different voltage levels, when power is supplied to the slave device, a clock signal is transmitted, and 0 is transmitted as the first signal When 0 is received as the second signal, transmission of 0 is stopped as the first signal, and thereafter, when a non-zero signal is received as the second signal, communication with the slave device is started. Features.

  In addition, the present disclosure is a slave device that can be connected to a host device through a plurality of interfaces having different voltage levels, is supplied with power from the host device, receives a clock signal, and receives 0 as a first signal Then, 0 is transmitted as the second signal, and thereafter, when a non-zero signal is received as the first signal, transmission of 0 as the second signal is stopped.

  The present disclosure also includes a removable system that includes the host device and the slave device.

  According to the present disclosure, it is possible to provide a host device, a slave device, and a removable system that can maintain interface compatibility and can be used safely even when a single-ended interface with a reduced signal voltage is introduced.

Block diagram showing the configuration of a conventional removable host system consisting of legacy host devices and legacy slave devices Diagram explaining the initialization routine of a removable system consisting of a legacy host device and a legacy slave device The figure explaining the initialization routine of non-UHS-I mode and UHS-I mode The block diagram which showed the structure of the removable system which consists of the conventional UHS-II host apparatus and a UHS-II slave apparatus The figure explaining the initialization routine of the removable system which consists of a UHS-II host device and a UHS-II slave device The block diagram which showed the structure of the removable system which consists of the LV-I host apparatus which made the output signal of the conventional legacy host apparatus 1.8V, and a legacy slave apparatus The block diagram which showed the structure of the removable system which consists of LV-I host apparatus and LV-I slave apparatus concerning Embodiment 1 of this invention The figure explaining the initialization routine of the removable system which consists of a LV-I host device and LV-I slave device concerning Embodiment 1 of this invention The block diagram which showed the structure of the removable system which consists of LV-I host apparatus and LV-I slave apparatus concerning Embodiment 2 of this invention. The figure explaining the initialization routine of the removable system which consists of LV-I host apparatus and LV-I slave apparatus concerning Embodiment 2 of this invention The block diagram which showed the structure of the removable system which consists of a LV-I host apparatus and a legacy slave apparatus concerning Embodiment 3 of this invention The figure explaining the initialization routine of the removable system which consists of a LV-I host apparatus and a legacy slave apparatus concerning Embodiment 3 of this invention The block diagram which showed the structure of the removable system which consists of LV-I host apparatus and UHS-II slave apparatus concerning Embodiment 4 of this invention The figure explaining the initialization routine of the removable system which consists of a LV-I host apparatus and UHS-II slave apparatus concerning Embodiment 4 of this invention The block diagram which showed the structure of the removable system which consists of a legacy host apparatus and LV-I slave apparatus concerning Embodiment 5 of this invention. The figure explaining the initialization routine of the removable system which consists of a legacy host apparatus and LV-I slave apparatus which supports a legacy interface concerning Embodiment 5 of this invention The figure explaining the initialization routine of the removable system which consists of a legacy host apparatus and LV-I slave apparatus which does not support a legacy interface concerning Embodiment 5 of this invention The block diagram which showed the structure of the removable system which consists of a UHS-II host apparatus and LV-I slave apparatus concerning Embodiment 6 of this invention The figure explaining the initialization routine of the removable system which consists of the LV-I slave apparatus which does not support the UHS-II host apparatus and UHS-II interface concerning Embodiment 6 of this invention The figure explaining the initialization routine of the removable system which consists of a UHS-II host apparatus and the LV-I slave apparatus which supports UHS-II interface concerning Embodiment 6 of this invention Block diagram showing an example of the configuration of the LV-I host device when the legacy slave device may drive the DAT0 line to a high level when the power is turned on

  Hereinafter, embodiments will be described in detail with reference to the drawings as appropriate. However, more detailed description than necessary may be omitted. For example, detailed descriptions of already well-known matters and repeated descriptions for substantially the same configuration may be omitted. This is to avoid the following description from becoming unnecessarily redundant and to facilitate understanding by those skilled in the art.

The inventor provides the accompanying drawings and the following description in order for those skilled in the art to fully understand the present disclosure, and is not intended to limit the subject matter described in the claims. Absent.
[1. Issues to be solved by the removable system according to the present disclosure]
First, problems to be solved by the removable system according to the present disclosure will be described with reference to FIGS. 1 to 6. Hereinafter, the interface is abbreviated as I / F as appropriate.

[1-1. Configuration of Legacy Host Device and Legacy Slave Device]
FIG. 1 is a block diagram illustrating a configuration of a removable system in which a legacy slave device 120 that can be inserted and removed is connected to a legacy host device 100 that supports a conventional single-ended I / F (hereinafter referred to as a legacy I / F). . As shown in FIG. 1, the legacy host device 100 includes at least a power supply unit 101 and a legacy I / F semiconductor chip 102. The legacy I / F semiconductor chip 102 includes at least an I / F signal regulator 103, a host device I / F unit 104, and an I / F control unit 105. The I / F signal regulator 103 can also be arranged outside the legacy I / F semiconductor chip 102.

  The legacy host device 100 and the legacy slave device 120 are mechanically connected. In addition, the legacy host device 100 is electrically connected to the legacy slave device 120 via the VDD1 line 110 that is a 3.3V power supply line.

  The legacy slave device 120 includes at least a legacy I / F semiconductor chip 121 and a back-end module 125. The back-end module 125 refers to a recording medium such as a flash memory or a device such as a wireless communication module. The legacy I / F semiconductor chip 121 includes at least an I / F signal regulator 122, a slave device I / F unit 123, and an I / F control unit 124. Note that the I / F signal regulator 122 can also be disposed outside the legacy I / F semiconductor chip 121.

  The host device I / F unit 104 and the slave device I / F unit 123 perform signal communication via the CLK line 111, the CMD line 112, and the DAT line 113. The DAT line 113 is composed of four signal lines: a DAT0 line 113a, a DAT1 line 113b, a DAT2 line 113c, and a DAT3 line 113d.

  FIG. 2 is a diagram illustrating a routine after power activation in the legacy host device 100 and the legacy slave device 120. FIG. 3 is a diagram illustrating details of commands and responses in two types of legacy slave devices 120 (details will be described later).

[1-2. Detailed operation of legacy host device and legacy slave device]
The operation when the legacy slave device 120 is connected to the legacy host device 100 will be described below with reference to FIGS.

  At the time of power activation, 3.3 V power is supplied from the power supply unit 101 of the legacy host device 100 to the legacy I / F semiconductor chip 102 and the I / F signal regulator 103 and further to the legacy slave device 120 via the VDD1 line 110. The The I / F signal regulator 103 is a device that appropriately converts the voltage of the supplied power supply according to an instruction from the I / F control unit 105 and outputs the converted voltage. The I / F signal regulator 103 outputs the 3.3 V power as it is immediately after the power is turned on, and supplies it to the legacy I / F semiconductor chip 102 and the host device I / F unit 104. The legacy I / F semiconductor chip 102 supplies the supplied 3.3V power to all modules arranged in the legacy I / F semiconductor chip 102 so that each module can be operated. The 3.3V power supplied to the host device I / F unit 104 is the source of the 3.3V signal on the CLK line 111, the CMD line 112, and the DAT line 113 output from the host device I / F unit 104. .

  On the other hand, the 3.3 V power supplied to the legacy slave device 120 via the VDD 1 line 110 is supplied to the legacy I / F semiconductor chip 121 and the I / F signal regulator 122. The I / F signal regulator 122 is a device that appropriately converts the voltage of the supplied power supply according to an instruction from the I / F control unit 124 and outputs it, and is input immediately after power is supplied from the legacy host device 100. The power is output as it is and supplied to the legacy I / F semiconductor chip 121 and the slave device I / F unit 123. The legacy I / F semiconductor chip 121 supplies the supplied 3.3V power supply to every module arranged in the legacy I / F semiconductor chip 121 so that each module can be operated. The 3.3V power supplied to the slave device I / F unit 123 is a source of the 3.3V signal of the CMD line 112 and the DAT line 113 output from the slave device I / F unit 123. Further, the 3.3V power supplied to the legacy slave device 120 is also supplied to the back-end module 125.

  The host device I / F unit 104 of the legacy host device 100 is connected to the slave device I / F unit 123 of the legacy slave device 120 by the CLK line 111, the CMD line 112, and the four DAT lines 113. On the CLK line 111, a single-ended clock signal is transmitted from the legacy host device 100 to the legacy slave device 120. In the CMD line 112, a command for the legacy host device 100 to control the legacy slave device 120 and a response corresponding to each command are transmitted by a single-ended method of 3.3V signal. Basically, the command is transmitted from the legacy host device 100 to the legacy slave device 120, and the response is transmitted from the legacy slave device 120 to the legacy host device 100. Therefore, the CMD line 112 is bidirectional communication.

  On the other hand, the DAT line 113 is a signal line that mainly transmits data contents such as still images and texts at high speed, and is composed of four signal lines. The configuration of the signal line is the same as that of the CMD line 112.

  The legacy host device 100 uses a pull-up resistor (not shown) for the CMD line 112 and all DAT lines 113 to prevent the signal lines from floating when the slave device is not attached. Pull up to the normal voltage (usually 3.3V).

  Further, the legacy host device 100 does not drive each terminal of the normal CMD line 112 and the DAT line 113 to either a low level (= 0, the same applies below) or a high level (= 1, the same applies below) when the power is turned on. The input state, that is, the high impedance (Hi-Z; release) state. Therefore, these signal lines are changed to a high level by the above-described pull-up resistor unless the legacy host device 100 is driven.

  In this specification, the signal being at a low level means that the voltage of the signal is 0 V and in the vicinity thereof, and usually means 0. On the other hand, a signal having a high level means that the voltage of the signal is higher than a low level and is easily distinguishable from a low level signal, and usually means 1.

  After the power supply is activated, the host device I / F unit 104 generates a 3.3 V signal single-ended clock using a 3.3 V (high voltage) power supply supplied from the I / F signal regulator 103. Then, after 1 ms or more has elapsed after the power supply output from the power supply unit 101 has stabilized at 3.3 V, the clock is supplied to the slave device I / F unit 123.

  Thereafter, the legacy host device 100 enters an initialization routine for performing characteristic confirmation and initialization of the connected legacy slave device 120. The host device I / F unit 104 first issues a reset command 200. There is no response corresponding to the reset command.

  Subsequently, an I / F condition check command 201a, which is a command for checking the I / F condition (for example, the corresponding power supply voltage) of the connected slave device, is generated by the I / F control unit 105, and is transmitted via the CMD line 112. To the slave device I / F unit 123.

  The I / F condition check command 201 a is transmitted to the I / F control unit 124 via the slave device I / F unit 123. The I / F control unit 124 interprets the content of the command, generates a corresponding response 201b, and returns it to the legacy host device 100 via the CMD line 112.

  Subsequently, the legacy host device 100 transmits an initialization command 202 a to the legacy slave device 120 via the CMD line 112. As in the case of the I / F condition check command 201a, the legacy slave device 120 interprets the contents of the command, generates a corresponding response 202b, and returns it to the legacy host device 100 via the CMD line 112.

  Thereafter, though not described in detail, the legacy host device 100 issues a write command 203a through a predetermined initialization process. At this time, after receiving the response 203b transmitted from the legacy slave device 120, the legacy host device 100 transmits data 203c to be written to the back-end module 125 of the legacy slave device 120 via the DAT line 113.

  In the legacy I / F, there are two types of I / Fs, non-UHS-I and UHS-I. The non-UHS-I is an I / F of a high voltage signal (hereinafter referred to as a 3.3V signal) in which the signal voltage of the CLK line 111, the CMD line 112, and the DAT line 113 is 3.3V from start to finish. On the other hand, UHS-I uses a 3.3V signal immediately after the power is turned on and switches to a 1.8V low voltage signal (hereinafter referred to as a 1.8V signal).

  A legacy slave device that supports only non-UHS-I is called a non-UHS-I slave device, and a legacy slave device that supports UHS-I and non-UHS-I is called a UHS-I slave device. The legacy host device 100 identifies whether the connected slave device is a non-UHS-I slave device or a UHS-I slave device by the UHS-I support flag. Note that the power supply voltage supplied to the non-UHS-I slave device and the UHS-I slave device via the power supply line is a 3.3V high voltage power supply.

  FIG. 3 is a diagram illustrating a difference in initialization between a non-UHS-I slave device and a UHS-I slave device. In FIG. 3, the CMD line and the DAT line are described as if they were one signal line in order to avoid making the figure complicated.

  The initialization command 202a described in FIG. 2 includes a UHS-I support confirmation bit for confirming whether or not a UHS-I slave device is connected. A host device supporting UHS-I can receive a UHS-I. Set 1 to the I support confirmation bit.

  The I / F control unit 124 of the legacy slave device 120 that has received the initialization command 202a returns a response 202b including at least a UHS-I support flag and an initialization completion flag, and starts initialization of the back-end module 125. The legacy slave device 120 can accept the initialization command 202a many times until the back-end module 125 shifts to the next process during initialization and after completion of initialization. If the initialization is in progress, 0 is set in the initialization completion flag of the response 202b. If the initialization is completed, 1 is set. When the UHS-I support confirmation bit of the initialization command 202a is set to 1, the UHS-I support flag of the non-UHS-I slave device is 0, and the UHS-I support flag of the UHS-I slave device is 1

  When the legacy host device 100 receives the response 202b including the initialization completion flag 1 within a predetermined time (for example, 64 clock periods) after issuing the initialization command 202a, the legacy host device 100 initializes the legacy slave device 120. Is determined to be complete.

  When the UHS-I support flag in the response 202b is set to 0, the legacy host device 100 determines that the connected legacy slave device 120 is a non-UHS-I slave device. In this case, between the legacy host device 100 and the legacy slave device 120, the clock transmitted via the CLK line 111, various commands and responses transmitted via the CMD line 112, and the DAT line 113 are transmitted. All of these data are realized by 3.3V signals. In FIG. 3A, the Write command 203a, the response 203b, and the data (content data) 203c are all transmitted by a 3.3V signal.

  A communication mode as shown in FIG. 3A is referred to as a non-UHS-I mode.

  On the other hand, when the UHS-I support flag of the response 202b is set to 1, the legacy host device 100 determines that the connected legacy slave device 120 is a UHS-I slave device.

  In this case, the legacy host device 100 transmits a voltage switching command 301a to the legacy slave device 120.

  The I / F control unit 124 that has received the voltage switching command 301a returns a corresponding response 301b, releases all the terminals of the slave device I / F unit 123, and then sends it to the I / F signal regulator 122. The output is instructed to be a 1.8V low voltage power supply (hereinafter referred to as a 1.8V power supply).

  When the I / F control unit 105 receives the response 301b from the legacy slave device 120, the legacy host device 100 drives the CLK line 111, the CMD line 112, and the DAT line 113 all low to transmit 0, In addition, it instructs the I / F signal regulator 103 to set the output to a 1.8V power supply.

  Thereafter, a clock based on the 1.8V signal is transmitted to the CLK line 111, and after a predetermined procedure, the legacy host device 100 and the legacy slave device 120 use the CMD line 112 to execute various commands and responses based on the 1.8V signal, The data transmitted through the DAT line 113 is transmitted by a 1.8V signal. In FIG. 3B, the Write command 203a, the response 203b, and the data 203c are all transmitted by a 1.8V signal.

  A communication mode as shown in FIG. 3B is referred to as a UHS-I mode.

  The details of the signal voltage switching sequence accompanying the voltage switching command 301a are disclosed in Patent Document 1.

[1-3. Configuration of UHS-II Host Device and UHS-II Slave Device]
In the single-end legacy I / F described above, the transmission speed per signal line is limited to about 200 Mbit / sec from the viewpoint of signal quality and EMI (Electro-Magnetic Interference). Therefore, in order to realize a higher transmission speed, a differential serial signal I / F called UHS-II is introduced in the SD card.

  FIG. 4 is a block diagram illustrating a configuration of a removable system in which a UHS-II slave device 420 that can be inserted and removed from the UHS-II host device 400 is connected. As shown in FIG. 4, the UHS-II host device 400 includes at least a first power supply unit 401, a second power supply unit 402, and a UHS-II semiconductor chip 403. The UHS-II semiconductor chip 403 includes at least an I / F signal regulator 404, a host device I / F unit 405, and an I / F control unit 406. Note that the I / F signal regulator 404 can also be disposed outside the UHS-II semiconductor chip 403.

  The UHS-II host device 400 and the UHS-II slave device 420 are mechanically connected. The UHS-II host device 400 is electrically connected to the UHS-II slave device 420 via a VDD2 line 411 which is a 1.8V power line in addition to a VDD1 line 410 which is a 3.3V power line. .

  The UHS-II slave device 420 includes at least a UHS-II semiconductor chip 421 and a back-end module 425. The UHS-II semiconductor chip 421 includes at least an I / F signal regulator 422, a slave device I / F unit 423, and an I / F control unit 424. The I / F signal regulator 422 can also be disposed outside the UHS-II semiconductor chip 421.

  The host device I / F unit 405 and the slave device I / F unit 423 perform signal communication via the RCLK line 412, the D0 line 413, and the D1 line 414. The D0 line 413 and the D1 line 414 are used only in UHS-II. The RCLK line 412, the D0 line 413, and the D1 line 414 are all differential serial signals having a voltage amplitude of 0.4V.

  The RCLK line 412 includes a DAT0 line 113a and a DAT1 line 113b in the legacy I / F.

  When the legacy slave device 120 is connected to the UHS-II host device 400, or when the UHS-II slave device 420 is connected to the legacy host device 100, communication can be performed using at least the legacy I / F. Therefore, the UHS-II host device 400 and the UHS-II slave device 420 are also provided with terminals used in the legacy I / F.

  The CLK line, CMD line, DAT2 line, and DAT3 line are not used in UHS-II. However, as described above, the UHS-II host device 400 or the UHS-II slave device 420 can operate in the legacy I / F. Electrically connected. On the other hand, the legacy host device 100 and the legacy slave device 120 that do not have the UHS-II function do not include the terminals of the VDD2 line 411, the D0 line 413, and the D1 line 414 that are used only in the UHS-II.

  FIG. 5 is a diagram illustrating a routine after the power is turned on in the UHS-II host device 400 and the UHS-II slave device 420.

[1-4. Detailed operation of UHS-II host device and UHS-II slave device]
Hereinafter, the operation when the UHS-II slave device 420 is connected to the UHS-II host device 400 will be described with reference to FIGS. 4 and 5.

  At the time of power activation, 3.3V power is supplied from the first power supply unit 401 of the UHS-II host device 400 to the UHS-II slave device 420 via the VDD1 line 410. In addition, 1.8V power from the second power supply unit 402 of the UHS-II host device 400 is supplied to the UHS-II semiconductor chip 403 and the I / F signal regulator 404 of the UHS-II host device 400 via the VDD2 line 411. The UHS-II slave device 420 is supplied.

  The UHS-II semiconductor chip 403 supplies the supplied 1.8V power to all modules arranged in the UHS-II semiconductor chip 403 so that each module can be operated. The I / F signal regulator 404 is a device that appropriately converts the voltage of the supplied 1.8V power supply and outputs it. In this example, the I / F signal regulator 404 steps down the voltage to 0.4V which is the amplitude of the differential signal. This is the source of the 0.4 V differential serial signals of the RCLK line 412 and the D0 line 413 that are supplied to the unit 405 and output from the host device I / F unit 405.

  On the other hand, the 3.3 V power supplied to the UHS-II slave device 420 via the VDD 1 line 410 is supplied to the back-end module 425. The 1.8V power supplied to the UHS-II slave device 420 via the VDD2 line 411 is supplied to the UHS-II semiconductor chip 421 and the I / F signal regulator 422. The UHS-II semiconductor chip 421 supplies the supplied 1.8V power to all modules arranged in the UHS-II semiconductor chip 421 so that each module can be operated. The 1.8 V power supplied to the I / F signal regulator 422 is stepped down to 0.4 V, supplied to the slave device I / F unit 423, and output from the slave device I / F unit 423. This is the source of the 414 0.4V differential serial signal.

  A differential reference clock of a differential serial system is transmitted from the UHS-II host device 400 to the UHS-II slave device 420 in one direction by the RCLK line 412 (configured by two signal lines DAT0 and DAT1). In addition, by using the D0 line 413 (configured by two signal lines), a differential serial signal (a symbol composed of a specific bit string in addition to commands and data) is in principle transferred from the UHS-II host device 400 to the UHS-II slave. Is transmitted to the device 420. In addition, by means of the D1 line 414 (configured by two signal lines), a differential serial type signal (a symbol composed of a specific bit string in addition to response and data) is in principle transferred from the UHS-II slave device 420 to the UHS-II host. Is transmitted to the device 400.

  In FIG. 5, the UHS-II host device 400 supplies 3.3V power to the UHS-II slave device 420 via the VDD1 line and 1.8V power via the VDD2 line. Then, after 1 ms or more has elapsed since the power output from the UHS-II host device 400 has stabilized at VDD1 = 3.3V and VDD2 = 1.8V, a differential reference clock is transmitted via the RCLK line 412. It should be noted that the regulation of the time until the differential reference clock is transmitted after stabilization of VDD1 and VDD2 is not necessarily 1 ms or more.

  Thereafter, the UHS-II host device 400 uses the STB. The L symbol 501a is transmitted to the UHS-II slave device 420 via the D0 line 413. STB. The I / F control unit 424 of the UHS-II slave device 420 that has correctly recognized the L symbol 501a has received the STB. BT within a predetermined time T (for example, 200 μs). The L symbol 501b is generated and transmitted to the UHS-II host apparatus 400 via the D1 line 414.

  The UHS-II host device 400 is connected to the STB. When the L symbol 501b is received, it is determined that UHS-II initialization is possible (UHS-II support determination).

  After that, although not shown in detail, a series of processes (503a to 503c) of various commands such as Write are executed through a predetermined UHS-II initialization process (such as the initialization command 502a and the response 502b).

  When using the DAT0 line 113a and the DAT1 line 113b as the RCLK line 412, the UHS-II host device 400 cuts off these pull-up resistors and drives them to a low level or a high level. When the UHS-II host apparatus 400 executes UHS-II initialization, the CMD line 112, the DAT2 line 113c, and the DAT3 line 113d are fixed at a low level or a high level. Realization of the high level may be realized by setting the signal line to the Hi-Z state by a pull-up resistor, or by driving the UHS-II host device 400 to the high level and transmitting “1”.

  Recently, due to miniaturization of semiconductor processes, it has become difficult for a semiconductor chip particularly for a host device to cope with a high voltage signal of 3.3V. For this reason, in a removable system composed of an SD card (slave device) and an SD card compatible host device, for example, it is required to introduce an I / F whose input / output is limited to a low voltage signal of 1.8V or less.

  On the other hand, many removable systems consisting of SD cards and SD card-compatible host devices are already widely used, and it is the host that replaces the form factors such as signal line layout and slave device size and shape with new ones. This is not preferable because both a device and a slave device need to be newly designed and cannot be used in host devices and slave devices already on the market, and it is preferable that a conventional interface can be used continuously.

  Here, UHS-II has a signal level that is much lower than that of 0.4V and 3.3V, and satisfies the requirement that it is a low voltage signal. However, UHS-II maintains the legacy I / F while maintaining UHS. In order to support −II, it is inevitable to increase the number of terminals of the semiconductor chip of each of the host device and the slave device, which leads to an increase in the cost of the semiconductor chip, and thus the host device and the slave device. Therefore, in addition to the conventional legacy I / F and UHS-II, only the low voltage signal of 1.8V is used without using the 3.3V signal, and the protocol including initialization is the same as the legacy I / F. The introduction of this I / F (hereinafter referred to as LV-I) is desired.

  Based on the above background, it is considered to introduce an LV-I compatible host device in which the input / output of the legacy I / F semiconductor chip 102 is limited to a low voltage signal (1.8 V) in the legacy host device 100 shown in FIG. It is done. FIG. 6 is a block diagram illustrating the configuration of a removable system composed of the LV-I host device 600 and the legacy slave device 120.

  The LV-I host device 600 includes at least a power supply unit 601 and an LV-I semiconductor chip 602. The LV-I semiconductor chip 602 includes at least an I / F signal regulator 603, a host device I / F unit 604, and an I / F control unit 605. The difference between the legacy host device 100 of FIG. 1 and the LV-I host device 600 of FIG. 6 is that the upper limit of the input signal withstand voltage of the LV-I semiconductor chip 602 is 1.8V.

  However, the following problems occur in the removable system shown in FIG.

  The output of the I / F signal regulator 603 of the LV-I host device 600 can be a 1.8V power supply instead of a 3.3V power supply after the power is turned on. On the other hand, when a legacy slave device 120 that supports 3.3V power supply, on which many products are already on the market, is connected to the LV-I host device 600, a 3.3V power supply is connected to the legacy slave device via the VDD1 line 110. 120. As described above, in the legacy slave device 120, the output of the I / F signal regulator 122 immediately after power activation is a 3.3V power supply. Therefore, the legacy slave device 120 returns the response 201b of the I / F condition check command 201a received for the first time after the power is turned on to the LV-I host device 600 with a 3.3V signal. As a result, a 3.3V signal is input to the LV-I semiconductor chip 602 of the LV-I host device 600, and the LV-I semiconductor chip 602 is destroyed.

  The above problem can be avoided by proceeding with the initialization only when the slave device connected to the LV-I host device is compatible with the LV-I interface, otherwise not performing the initialization.

  As a method for the host device to detect the characteristics of the slave device, a method of reading a register mounted on the slave device is common. However, the register of the slave device is normally valid after completion of initialization triggered by the initialization command (202a or 502a). Therefore, the host device needs to detect the characteristics of the slave device before the initialization is performed. This method cannot be applied to solve this problem.

  In order to solve this problem, before the host device issues a command, it is necessary for the slave device to control the specific signal line to a state different from that at the time of power activation and to cause the host device to detect it. .

The inventor has recognized this problem in the process of developing a removable system and has come up with a solution. The details of the solution will be specifically described below. In the following description, Embodiments 1 and 2 will be described as examples in which the technical idea of the solving means is embodied.
[2. Configuration and Operation of Removable System According to First Embodiment]
[2-1. Constitution]
FIG. 7 is a block diagram illustrating a configuration of a removable system in which an LV-I slave device 720 that can be inserted and removed is connected to the LV-I host device 700 of the present invention. As shown in FIG. 7, the LV-I host device 700 includes at least a power supply unit 701 and an LV-I semiconductor chip 702. The LV-I semiconductor chip 702 includes an I / F signal regulator 703, a host device I / F unit 704, and an I / F control unit 705. The host device I / F unit 704 receives at least a clock signal transmitting unit that transmits a clock signal, a transmitting unit that transmits data on the DAT1 line that is the first signal, and data on the DAT2 line that is the second signal It has the function of the receiving part.

  The upper limit of the input signal withstand voltage of the LV-I semiconductor chip 702 of the LV-I host device 700 is 1.8V. Further, the I / F signal regulator 703 can be disposed outside the LV-I semiconductor chip 702. Furthermore, the host device according to the present embodiment includes the power supply unit 701 and the LV-I semiconductor chip 702. If power can be supplied to the LV-I semiconductor chip 702, the LV-I semiconductor is used. The host device of this embodiment can be realized even with the chip 702 alone.

  The LV-I host device 700 and the LV-I slave device 720 are mechanically connected. Further, the LV-I host device 700 is electrically connected to the LV-I slave device 720 via the VDD1 line 710 as in the removable system described in FIG.

  The LV-I slave device 720 includes at least an LV-I semiconductor chip 721 and a back-end module 725. The LV-I semiconductor chip 721 includes at least an I / F signal regulator 722, a slave device I / F unit 723, and an I / F control unit 724. The slave device I / F unit 723 transmits at least a clock signal receiving unit that receives a clock signal, a receiving unit that receives the first signal on the DAT1 line, and a data signal that is transmitted on the DAT2 line that is the second signal. Part function.

  The I / F signal regulator 722 can also be disposed outside the LV-I semiconductor chip 721. Furthermore, although the slave device in the present embodiment is composed of the LV-I semiconductor chip 721 and the back-end module 725, the slave device of the present embodiment can be realized even with the LV-I semiconductor chip 721 alone.

  The host device I / F unit 704 and the slave device I / F unit 723 perform signal communication via the CLK line 711, the CMD line 712, and the DAT line 713, as in the removable system described with reference to FIG. The DAT line 713 includes four signal lines, a DAT0 line 713a, a DAT1 line 713b, a DAT2 line 713c, and a DAT3 line 713d.

  FIG. 8 is a diagram for explaining the operation after power activation in the removable system configured by the LV-I host device 700 and the LV-I slave device 720 in the present embodiment.

[2-2. Detailed operation]
The operation when the LV-I slave device 720 is connected to the LV-I host device 700 will be described below with reference to FIGS.

  In this embodiment, at the time of power activation, the DAT1 line 713b and the DAT2 line 713c are in the Hi-Z state in both the LV-I host device 700 and the LV-I slave device 720. Since these signal lines are pulled up to a predetermined voltage by a pull-up resistor in the LV-I host device 700 (not shown), the signal lines transition to a high level unless the signal lines are driven. Note that the voltage of the signal to be pulled up must not exceed the upper limit of the input signal withstand voltage of the host device I / F unit 704. In this embodiment, it is assumed that the DAT1 line 713b and the DAT2 line 713c are pulled up to 1.8V by the LV-I host device 700.

  At the time of power activation, 3.3V power is supplied from the power supply unit 701 of the LV-I host device 700 to the LV-I semiconductor chip 702 and the I / F signal regulator 703 and further via the VDD1 line 710 to the LV-I slave device 720. To be supplied. The LV-I semiconductor chip 702 supplies the supplied 3.3V power to all modules arranged in the LV-I semiconductor chip 702 so that each module can operate.

  The I / F signal regulator 703 converts the supplied 3.3V power supply to 1.8V and supplies it to the host device I / F unit 704. The 1.8V power supplied to the host device I / F unit 704 is the source of the 1.8V signal on the CLK line 711, the CMD line 712, and the DAT line 713 output from the host device I / F unit 704. .

  On the other hand, the 3.3 V power supplied to the LV-I slave device 720 via the VDD1 line 710 is supplied to the LV-I semiconductor chip 721, the I / F signal regulator 722, and the back-end module 725.

  The LV-I semiconductor chip 721 supplies the supplied 3.3V power to all modules arranged in the LV-I semiconductor chip 721 so that each module can be operated. The I / F signal regulator 722 is a device that appropriately converts the voltage of the supplied power supply according to an instruction from the I / F control unit 724 and outputs it. Immediately after power is supplied from the LV-I host device 700, The input power is output as it is and supplied to the slave device I / F unit 723. It is desirable that the I / F signal regulator 722 is started immediately after the 3.3V power is supplied so that the 1.8V power can be quickly output. As will be described later, when communication is started between the LV-I host device 700 and the LV-I slave device 720, the I / F signal regulator 722 converts the supplied 3.3V power supply to 1.8V. To the slave device I / F unit 723. The 1.8V power supplied to the slave device I / F unit 723 is the source of the 1.8V signal on the CLK line 711, the CMD line 712, and the DAT line 713 output from the slave device I / F unit 723. .

  Similar to the removable system described in FIG. 1, the host device I / F unit 704 of the LV-I host device 700 has a CLK line 711, a CMD line 712, and four DAT lines 713 as slaves of the LV-I slave device 720. A device I / F unit 723 is connected.

  In FIG. 8, when the LV-I host device 700 tries to initialize with the LV-I, at least the DAT1 line 713b and the DAT2 line 713c are set to the Hi-Z state. At this time, the DAT1 line 713b and the DAT2 line 713c are both set to a high level by pull-up resistors of signal lines (not shown).

  The LV-I host device 700 supplies 3.3V power to the LV-I slave device 720 via the VDD1 line. After 1 ms or more has elapsed since the power supply output VDD1 from the LV-I host device 700 has stabilized at 3.3V, the LV-I host device 700 receives a 1.8V single-ended clock via the CLK line 711. Transmit to the LV-I slave device 720. Note that the regulation of the time until the clock is supplied after VDD1 is stabilized is not necessarily 1 ms or more. Further, the LV-I host device 700 instructs the host device I / F unit 704 to drive the DAT1 line 713b to a low level and transmit 0 (801). In FIG. 8, the DAT1 line 713b is set to the low level after the 1.8 V single-ended clock is supplied, but may be at another timing such as simultaneously with the clock supply.

  The LV-I slave device 720 includes VDD1 (3.3V power supply) by the I / F signal regulator 722, 1.8V single-ended clock of the CLK line 711 by the slave device I / F unit 723, and the DAT1 line 713b. When all of the low-level signals at are detected, the detection result is transmitted to the I / F control unit 724. At this time, the I / F control unit 724 determines that the host device is trying to initialize with the LV-I interface, and drives the DAT2 line 713c to the low level with respect to the slave device I / F unit 723. Instruct to transmit 0 (802).

  When the LV-I host device 700 detects that the DAT2 line 713c is at a low level by a predetermined time, it notifies the I / F control unit 705. At this time, the I / F control unit 705 determines that the LV-I slave device 720 corresponding to LV-I is connected, stops the drive of the DAT1 line 713b to the host device I / F unit 704, and returns to 0. To not send. As a result, the DAT1 line 713b transits to a high level by the pull-up resistor on the LV-I host device 700 side (803).

  When the slave device I / F unit 723 of the LV-I slave device 720 detects that the DAT1 line 713b is at a low level, it notifies the I / F control unit 724. At this time, the I / F control unit 724 instructs the I / F signal regulator 722 to output the 1.8V power after confirming whether the startup is completed and the 1.8V power can be output. To do. Then, the slave device I / F unit 723 is instructed not to stop driving the DAT2 line 713c and transmit 0. As a result, the DAT2 line 713c transits to a high level by the pull-up resistor on the LV-I host device 700 side (804).

  When the host device I / F unit 704 of the LV-I host device 700 detects that the DAT2 line 713c is at a high level, it notifies the I / F control unit 705 (805). At this time, the I / F control unit 705 starts an initialization process for the LV-I slave device 720. Further, after the initialization process, the signals of the CMD line 712 and the DAT line 713 transmitted from the LV-I host device 700 are all 1.8V.

  The I / F control unit 705 transmits an I / F condition check command 807 a to the LV-I slave device 720 following the reset command 806 via the CMD line 712. In the I / F condition check command 807a, a parameter including a check bit indicating whether or not the 1.8V signal is supported is multiplexed.

  The LV-I slave device 720 that has received the I / F condition check command 807a checks the parameters multiplexed in the I / F condition check command 807a. When the LV-I slave device 720 confirms the above parameters, it can double check that the connected host device is the LV-I host device 700.

  Thereafter, the LV-I slave device 720 transmits a corresponding response 807 b to the LV-I host device 700 via the CMD line 712. After this process, initialization at the LV-I interface and data exchange by the data 808 are performed.

[2-3. effect]
According to the first embodiment of the present invention, the LV-I host device 700 supplies a 3.3V power supply VDD1, a 1.8V single-ended clock, and a low level signal via the DAT1 line 713b almost simultaneously. As a result, the start of initialization by the LV-I interface is notified to the LV-I slave device 720.

  Also, since the VDD1, the single-ended clock, and the low level signal from the DAT1 line 713b are supplied almost simultaneously only to the LV-I host device 700, the LV-I slave device 720 immediately after the VDD1 power supply is stabilized. When all of these are detected, the LV-I slave device 720 recognizes that the LV-I interface is being initialized, and drives the DAT2 line 713c to a low level to transmit 0.

  The LV-I host device 700 that has detected that the DAT2 line 713c is at a low level detects that the slave device is the LV-I slave device 720. As a result, the response received via the CMD line 712 and the data received via the DAT line 713 are all guaranteed to be 1.8V signals. Therefore, even if the LV-I host device 700 continues the subsequent processing, the 3.3V high voltage signal is not supplied to the LV-I host device 700, so the upper limit of the input signal withstand voltage is 1.8V. The host device I / F unit 704 is not destroyed.

  Since the LV-I host device 700 puts the DAT2 line 713c in the Hi-Z state before supplying power, the LV-I slave device 720 drives the DAT2 line 713c to the low level at the timing 802 in FIG. Even if 0 is transmitted, the host device I / F unit 704 is not adversely affected.

The LV-I host device 700 performs initialization after confirming that the DAT2 line 713c is at a high level, that is, the LV-I slave device 720 is not driving the DAT2 line 713c. Thereby, since the LV-I host device 700 and the LV-I slave device 720 do not drive the DAT2 line 713c at the same time, it is possible to avoid the problem of driving different signal levels from both.
[3. Configuration and Operation of Removable System According to Second Embodiment]
[3-1. Constitution]
FIG. 9 is a block diagram illustrating the configuration of a removable system in which an LV-I slave device 920 that can be inserted and removed is connected to the LV-I host device 900 of the present invention.

  As illustrated in FIG. 9, the LV-I host device 900 includes at least a first power supply unit 901, a second power supply unit 902, and an LV-I semiconductor chip 903. The LV-I semiconductor chip 903 includes a host device I / F unit 904 and an I / F control unit 905. The upper limit of the input signal withstand voltage of the LV-I semiconductor chip 903 of the LV-I host device 900 is 1.8V. The LV-I host device 900 and the LV-I slave device 920 are mechanically connected. Further, the LV-I host device 900 is electrically connected to the LV-I slave device 920 via the VDD1 line 910 and the VDD2 line 911 as in the removable system described with reference to FIG.

  The LV-I slave device 920 includes at least an LV-I semiconductor chip 921 and a back-end module 925. The LV-I semiconductor chip 921 includes at least a VDD1 detection unit 922, a slave device I / F unit 923, and an I / F control unit 924. The VDD1 detection unit 922 can also be disposed inside the slave device I / F unit 923 or outside the LV-I semiconductor chip 921.

  The host device I / F unit 904 and the slave device I / F unit 923 perform signal communication through the CLK line 912, the CMD line 913, and the DAT line 914, as in the removable system described with reference to FIG. The DAT line 914 is composed of four signal lines, a DAT0 line 914a, a DAT1 line 914b, a DAT2 line 914c, and a DAT3 line 914d.

  Although the LV-I host device 700 and the LV-I slave device 720 according to the first embodiment do not have the VDD2 terminal, the present embodiment is different in that both have the VDD2 terminal.

  FIG. 10 is a diagram for explaining the operation after power activation in the removable system configured with the LV-I host device 900 and the LV-I slave device 920 in the present embodiment.

[3-2. Detailed operation]
Hereinafter, with reference to FIG. 9 and FIG. 10, an operation when the LV-I slave device 920 is connected to the LV-I host device 900 will be described with respect to portions different from the first embodiment.

  At the time of power activation, 3.3V power is supplied from the first power supply unit 901 of the LV-I host device 900 to the LV-I slave device 920 via the VDD1 line 910. In addition, the 1.8V power supply from the second power supply unit 902 of the LV-I host device 900 is further connected to the LV-I semiconductor chip 903 and the host device I / F unit 904 of the LV-I host device 900 by further providing a VDD2 line 911. Via the LV-I slave device 920.

  The LV-I semiconductor chip 903 supplies the supplied 1.8V power to all modules arranged in the LV-I semiconductor chip 903 so that each module can be operated. The 1.8V power supplied to the host device I / F unit 904 is the source of the 1.8V signal on the CLK line 912, the CMD line 913, and the DAT line 914 output from the host device I / F unit 904. Become.

  On the other hand, the 3.3 V power supplied to the LV-I slave device 920 via the VDD 1 line 910 is supplied to the back-end module 925. Also, the VDD1 detection unit 922 detects the presence or absence of VDD1, and notifies the I / F control unit 924 of the result via the slave device I / F unit 923.

  In addition, the 1.8V power supplied from the LV-I host device 900 via the VDD2 line 911 is supplied to the LV-I semiconductor chip 921 and the slave device I / F unit 923. The LV-I semiconductor chip 921 supplies the supplied 1.8V power to all modules arranged in the LV-I semiconductor chip 921 so that each module can be operated.

  In FIG. 10, when the LV-I host device 900 tries to initialize with the LV-I, at least the DAT1 line 914b and the DAT2 line 914c are set to the Hi-Z state. At this time, both the DAT1 line 914b and the DAT2 line 914c are set to the high level by pull-up resistors of the signal lines (not shown).

  The LV-I host device 900 supplies 3.3V power to the LV-I slave device 920 through the VDD1 line 910 and 1.8V power through the VDD2 line 911. Note that the order in which the LV-I host device 900 starts up VDD1 and VDD2 does not matter. Then, after 1 ms or more has elapsed since the power supply output from the LV-I host device 900 has stabilized at VDD1 = 3.3V and VDD2 = 1.8V, the LV-I host device 900 passes 1 through the CLK line 912. .8V single-ended clock is transmitted to the LV-I slave device 920. Note that the definition of the time until the clock is supplied after VDD1 and VDD2 are stabilized is not necessarily 1 ms or more.

  Further, the LV-I host device 900 instructs the host device I / F unit 904 to drive the DAT1 line 914b to a low level and transmit 0 (801). In FIG. 10, the DAT1 line 914b is set to the low level after the 1.8 V single-ended clock is supplied, but may be at another timing such as simultaneously with the clock supply.

  The operations after 801 are the same as those in the first embodiment. In this embodiment, since the I / F signal regulator 722 does not exist, it is not necessary to confirm the activation of the I / F signal regulator in 804.

  As described above, also in the present embodiment, initialization by the LV-I interface and data exchange by the data 808 are performed as in the first embodiment.

[3-3. effect]
According to the second embodiment of the present invention, a configuration in which the LV-I host device 900 supplies VDD2 that is a 1.8V power supply to the LV-I slave device 920 is added to the first embodiment. It can be seen that the same effect can be obtained.

The present embodiment is characterized in that the I / F signal regulators 703 and 722 in the first embodiment are unnecessary. As a result, power consumption by the I / F signal regulator can be reduced in both the LV-I host device 900 and the LV-I slave device 920. As a result, there is an effect that the continuous operation time can be lengthened particularly in a mobile removable system in which the LV-I host device is driven by a battery.
[4. Configuration and Operation of Removable System According to Third Embodiment]
The LV-I host device and LV-I slave device described in the third and subsequent embodiments will be described as operating in principle based on the contents described in the first embodiment.

[4-1. Constitution]
FIG. 11 is a block diagram illustrating the configuration of a removable system in which the legacy slave device 120 that can be inserted and removed is connected to the LV-I host device 700 of the present invention. The configurations of the LV-I host device 700 and the legacy slave device 120 are the same as those described so far.

  The LV-I host device 700 and the legacy slave device 120 are mechanically connected. The LV-I host device 700 is electrically connected only by the VDD1 line 1110.

  The host device I / F unit 704 and the slave device I / F unit 123 perform signal communication via the CLK line 1111, the CMD line 1112, and the DAT line 1113. The DAT line 1113 includes four signal lines, a DAT0 line 1113a, a DAT1 line 1113b, a DAT2 line 1113c, and a DAT3 line 1113d.

  FIG. 12 is a diagram for explaining the operation after power activation in the removable system configured with the LV-I host device 700 and the legacy slave device 120 in the present embodiment.

[4-2. Detailed operation]
Hereinafter, the operation when the legacy slave device 120 is connected to the LV-I host device 700 will be described with reference to FIGS. 11 and 12.

  The 3.3V power supplied to the legacy slave device 120 via the VDD1 line 1110 is supplied to the legacy I / F semiconductor chip 121 and the back-end module 125, and becomes operable.

  As in the first embodiment, when the power is turned on, the DAT1 line 1113b and the DAT2 line 1113c are in the Hi-Z state in both the LV-I host device 700 and the legacy slave device 120. Therefore, each signal line becomes high level by a pull-up resistor (not shown).

  After 1 ms or more has elapsed after the power supply output from the LV-I host device 700 has stabilized at VDD1 = 3.3 V, the LV-I host device 700 receives a 1.8 V single-ended clock via the CLK line 1111, and A low level signal is transmitted to the legacy slave device 120 via the DAT1 line 1113b.

  By the way, unlike the LV-I slave device 720, the legacy slave device 120 drives the DAT2 line 1113c to low level and transmits 0 when it detects all of the VDD1, clock, and low level signals on the DAT1 line 1113b. It does not have a function to do. Therefore, the LV-I host device 700 does not detect that the DAT2 line 1113c is at a low level.

  When the LV-I host device 700 does not detect that the DAT2 line 1113c is at a low level by a predetermined time, the LV-I host device 700 does not detect that the slave device is the LV-I slave device 720, that is, the LV -It determines that the I interface is not supported, and stops initialization on the LV-I interface.

[4-3. effect]
According to the third embodiment of the present invention, the legacy slave device 120 does not transmit 0 by driving the DAT2 line 1113c to a low level immediately after activation. Therefore, the LV-I host device 700 monitors the DAT2 line 1113c, and detects that the slave device does not support LV-I if it does not detect that the level becomes low by a predetermined time. Do not perform the initialization process. Thus, since a 3.3V high voltage signal is not supplied to the LV-I host device 700 from a slave device that is not the LV-I slave device 720, the upper limit of the input signal withstand voltage is 1.8V. The I / F unit 704 is not destroyed.

Even if the LV-I host device according to the present embodiment has a function of supplying 1.8V power via VDD2 as in the second embodiment, the legacy slave device 120 is supplied with VDD2. Since there is no terminal, similar results are obtained.
[5. Configuration and Operation of Removable System According to Fourth Embodiment]
[5-1. Constitution]
FIG. 13 is a block diagram illustrating the configuration of a removable system in which a UHS-II slave device 420 that can be inserted and removed is connected to the LV-I host device 700 of the present invention. The configurations of the LV-I host device 700 and the UHS-II slave device 420 are the same as those described so far.

  The LV-I host device 700 and the UHS-II slave device 420 are mechanically connected. The LV-I host device 700 is electrically connected to the UHS-II slave device 420 via the VDD1 line 1310.

  The host device I / F unit 704 and the slave device I / F unit 423 perform signal communication via the CLK line 1311, the CMD line 1312, and the DAT line 1313. The DAT line 1313 is composed of four signal lines: a DAT0 line 1313a, a DAT1 line 1313b, a DAT2 line 1313c, and a DAT3 line 1313d.

  FIG. 14 is a diagram for explaining an operation after power activation in a removable system composed of the LV-I host device 700 and the UHS-II slave device 420.

[5-2. Detailed operation]
The operation when the UHS-II slave device 420 is connected to the LV-I host device 700 will be described below with reference to FIGS. 13 and 14.

  At the time of power activation, 3.3 V power is supplied from the power supply unit 701 of the LV-I host device 700 to the UHS-II slave device 420 via the VDD 1 line 710.

  On the other hand, since the LV-I host device 700 does not supply VDD2, VDD2 is not supplied to the UHS-II semiconductor chip 421 in the UHS-II slave device 420.

  In general, it is known that if a signal is supplied to a semiconductor chip in a state where power is not supplied, the semiconductor chip is adversely affected. In order to avoid such a situation, in the present embodiment, when the 1.8V power is not supplied to the UHS-II semiconductor chip 421 via VDD2, the 3.3V signal supplied via VDD1 instead. Is supplied to the UHS-II semiconductor chip 421.

  At power-on, the DAT1 line 1313b and the DAT2 line 1313c are in the Hi-Z state in both the LV-I host device 700 and the UHS-II slave device 420. Therefore, each signal line becomes high level by a pull-up resistor (not shown).

  After 1 ms or more has elapsed after the power supply output from the LV-I host device 700 has stabilized at VDD1 = 3.3 V, the LV-I host device 700 receives a 1.8 V single-ended clock via the CLK line 1311, and A low level signal is transmitted to the UHS-II slave device 420 via the DAT1 line 1313b.

  Similar to the legacy slave device 120 described in the third embodiment, the UHS-II slave device 420 also sets the DAT2 line 1313c to a low level when all low level signals on the VDD1, CLK, and DAT1 lines 1313b are detected. It does not have a function to drive and send 0. Therefore, the LV-I host device 700 does not detect that the DAT2 line 1313c is at a low level.

  As in the third embodiment, when the LV-I host device 700 does not detect that the DAT2 line 1313c is at a low level by a predetermined time, the LV-I host device 700 determines that the slave device is an LV- It is determined that I is not supported, and initialization at the LV-I interface is stopped.

[5-3. effect]
According to the fourth embodiment of the present invention, the UHS-II slave device 420 does not transmit 0 by driving the DAT2 line 1313c to a low level immediately after activation. Therefore, the LV-I host device 700 monitors the DAT2 line 1313c, and detects that the slave device does not support LV-I unless it detects that the level becomes low by a predetermined time. Do not perform the initialization process. In addition, since a 3.3V high voltage signal is not supplied to the LV-I host device 700, the host device I / F unit 704 whose input signal withstand voltage has an upper limit of 1.8V is not destroyed.

Note that when the LV-I host device in this embodiment has a function of supplying 1.8 V power via VDD 2 as in the second embodiment, the UHS-II semiconductor chip 421 and the I / F signal regulator 422 A 1.8V signal is supplied. In this case, as described with reference to FIG. 4, the UHS-II semiconductor chip 421 is driven by VDD2, and the UHS-II slave device 420 may not supply VDD1 to the UHS-II semiconductor chip 421 (results). The same effect is obtained that the initialization of the LV-I interface is canceled.
[6. Configuration and Operation of Removable System According to Embodiment 5]
[6-1. Constitution]
FIG. 15 is a block diagram illustrating the configuration of a removable system to which the LV-I slave device 720 of the present invention that can be inserted into and removed from the legacy host device 100 is connected. The configurations of the legacy host device 100 and the LV-I slave device 720 are the same as those described above. It is assumed that the LV-I slave device 720 according to the present embodiment supports legacy I / F. Therefore, the upper limit of the input signal withstand voltage of the slave device I / F unit 723 of the LV-I slave device 720 is 3.3V.

  The legacy host device 100 and the LV-I slave device 720 are mechanically connected. The legacy host device 100 is electrically connected to the legacy slave device 120 via a VDD1 line 1510 that is a 3.3V power supply line.

  The host device I / F unit 104 and the slave device I / F unit 723 perform signal communication via the CLK line 1511, the CMD line 1512, and the DAT line 1513. The DAT line 1513 includes four signal lines, a DAT0 line 1513a, a DAT1 line 1513b, a DAT2 line 1513c, and a DAT3 line 1513d.

  FIG. 16 is a diagram for explaining the operation after power activation in the removable system composed of the legacy host device 100 and the LV-I slave device 720.

[6-2. Detailed operation]
The operation when the LV-I slave device 720 is connected to the legacy host device 100 will be described below with reference to FIGS. 15 and 16.

  In this embodiment, at the time of power activation, the DAT1 line 1513b and the DAT2 line 1513c are in the Hi-Z state in both the legacy host device 100 and the LV-I slave device 720. Therefore, each signal line at the time of power activation is at a high level by a pull-up resistor (not shown).

  At the time of power activation, 3.3 V power is supplied from the power supply unit 101 of the legacy host device 100 to the LV-I slave device 720 via the VDD1 line 1510. The 3.3 V power supplied to the LV-I slave device 720 via the VDD1 line 1510 is supplied to the LV-I semiconductor chip 721, the I / F signal regulator 722, and the back-end module 725.

  Immediately after power is supplied from the LV-I host device 700, the I / F signal regulator 722 outputs the input power as it is and supplies it to the slave device I / F unit 723.

  After 1 ms or more has elapsed after the power supply output from the legacy host device 100 has stabilized at VDD1 = 3.3 V, the legacy host device 100 sends a 3.3 V single-ended clock to the LV-I slave device via the CLK line 1511. To 720. However, unlike the LV-I host device 700, the legacy host device 100 does not transmit 0 by driving the DAT1 line 1513b to a low level at this time (1601).

  The LV-I slave device 720 detects VDD1 (3.3V power supply) by the I / F signal regulator 722 and 3.3V single-ended clock of the CLK line 1511 by the slave device I / F unit 723. Since it is not detected that the DAT1 line 1513b is at low level, 0 is not transmitted by driving the DAT2 line 1513c to low level (1602).

  At this time, the LV-I slave device 720 determines that the legacy I / F has been initialized, and notifies the I / F control unit 724 accordingly.

  On the other hand, the legacy host device 100 transmits the I / F condition check command 1604a to the LV-I slave device 720 following the reset command 1603 without particularly checking the level of the DAT2 line 1513c.

  The I / F control unit 724 of the LV-I slave device 720 that has received the I / F condition check command 1604a confirms the contents of the I / F condition check command 1604a, generates a corresponding response 1604b, and generates a CMD line. It returns to the legacy host device 100 via 1512. After this process, initialization at the legacy interface and data exchange are performed.

[6-3. effect]
According to the fifth embodiment of the present invention, when the LV-I slave device 720 is connected to the legacy host device 100, the legacy host device 100 does not drive the DAT1 line 1513b to the low level immediately after startup, so 0 is transmitted. In other words, the LV-I slave device 720 cannot detect all of the low level signals on the VDD1, the clock, and the DAT1 line 1513b. At this time, the LV-I slave device 720 determines that the LV-I interface is not initialized, and does not drive the DAT2 line 1513c to a low level, so that 0 is not transmitted.

  Thereafter, the legacy host device 100 starts initialization of the legacy I / F. However, since the LV-I slave device 720 of this embodiment supports the legacy I / F, as a result, the legacy host device 100 performs initialization at the legacy interface. It will be successful.

  Although the present embodiment has been described on the assumption that the LV-I slave device 720 also supports the legacy I / F, the same holds true even when the LV-I slave device 720 does not support it.

  As shown in FIG. 17, the LV-I slave device 720 that does not support the legacy I / F does not transmit the corresponding response 1604b when confirming the content of the I / F condition check command 1604a. The legacy host device 100 determines that the slave device does not support the legacy I / F when the response 1604b is not received even after a predetermined time has elapsed after transmitting the I / F condition check command 1604a, and the subsequent processing Cancel.

  However, in this case, since the 3.3V signal is supplied from the legacy host device 100 to the LV-I slave device 720 without prior confirmation, even if the LV-I slave device 720 does not support the legacy I / F. Even so, at least the upper limit of the input signal withstand voltage of the slave device I / F unit 723 needs to be 3.3V.

Even if the LV-I slave device in the present embodiment has a function of receiving 1.8 V power supply via VDD2 as in the second embodiment, the legacy host device 100 supplies VDD2. Since there is no terminal, similar results are obtained.
[7. Configuration and Operation of Removable System According to Embodiment 6]
[7-1. Constitution]
FIG. 18 is a block diagram illustrating the configuration of a removable system to which the LV-I slave device 720 of the present invention that can be inserted into and removed from the UHS-II host device 400 is connected.

  The configurations of the UHS-II host device 400 and the LV-I slave device 720 are the same as those described so far. Here, the RCLK line 1812 includes a DAT0 line 1812a and a DAT1 line 1812b. In the UHS-II I / F, unused signal lines are a DAT2 line 1813a, a DAT3 line 1813b, a CMD line 1813c, and a CLK line 1813d. Note that the LV-I slave device 720 of the present embodiment does not support UHS-II.

  The UHS-II host device 400 and the LV-I slave device 720 are mechanically connected. Further, the UHS-II host device 400 is electrically connected to the LV-I slave device 720 via a VDD1 line 1810 which is a 3.3V power supply line. In addition to the VDD1 line 1810, the UHS-II host device 400 has a VDD2 line 1811 which is a 1.8V power supply line. However, since the LV-I slave device 720 does not have a terminal for the VDD2 line, VDD2 is not supplied. .

  The host device I / F unit 405 and the slave device I / F unit 723 are connected by an RCLK line 1812. The UHS-II host device 400 includes terminals of the D0 line 1814 and the D1 line 1815, whereas the LV-I slave device 720 does not include the terminals of the D0 line 1814 and the D1 line 1815. Signal transmission using line 1814 and D1 line 1815 is impossible.

  The DAT2 line 1813a, the DAT3 line 1813b, the CMD line 1813c, and the CLK line 1813d are not used in the UHS-II. It is in an electrically connected state so that it can operate even with LV-I.

  FIG. 19 is a diagram illustrating a routine after the power is turned on in the UHS-II host device 400 and the LV-I slave device 720.

[7-2. Detailed operation]
Hereinafter, the operation when the LV-I slave device 720 is connected to the UHS-II host device 400 will be described with reference to FIGS. 18 and 19.

  At the time of power activation, 3.3V power is supplied from the first power supply unit 401 of the UHS-II host device 400 to the LV-I slave device 720 via the VDD1 line 1810. In addition, 1.8V power is output from the second power supply unit 402 of the UHS-II host device 400 to the VDD2 line 1811.

The states of the five signal lines of the UHS-II host device 400, that is, the DAT0 line 1812a, the DAT1 line 1812b, the DAT2 line 1813a, the DAT3 line 1813b, and the CMD line 1813c are not defined. That is,
(1) High level as a result of a pull-up resistor in the Hi-Z state (2) Driven to low level by the UHS-II host device 400 (3) High by the UHS-II host device 400 One that is driven to the level.

  The CLK line 1813d is normally driven to a fixed low level by the UHS-II host device 400 because there is no pull-up resistor.

  In FIG. 17, the UHS-II host apparatus 400 supplies 3.3V power to the LV-I slave apparatus 720 via the VDD1 line. However, as described above, since the LV-I slave device 720 does not have a terminal of the VDD2 line, VDD2 is not supplied to the LV-I slave device 720.

  Then, after 1 ms or more has elapsed since the power output from the UHS-II host device 400 has stabilized at VDD1 = 3.3V and VDD2 = 1.8V, a differential reference clock is transmitted via the RCLK line 1812.

  At this time, although the LV-I slave device 720 detects VDD1, the CLK line 1813d is fixed at a low level, and thus is not detected as a clock that periodically repeats a high level and a low level. Furthermore, since RCLK is supplied via the DAT1 line 1812b, the DAT1 line 1812b periodically varies. Therefore, a fixed low level signal cannot be detected from the DAT1 line 1812b (1901).

  Therefore, the LV-I slave device 720 determines that the LV-I is not initialized, and notifies the I / F control unit 724 accordingly. Since it is determined that the LV-I is not initialized, the DAT2 line 1813a is not driven to a low level, and as a result, 0 is not transmitted (1902).

  On the other hand, the UHS-II host device 400 does not particularly check the level of the DAT2 line 1813a, and does not check the level of the STB. L symbol 1903a is transmitted. However, since the LV-I slave device 720 of this embodiment does not support UHS-II, the STB. The L symbol 1903b cannot be transmitted. The UHS-II host device 400 transmits the STB. When the L symbol 1903b cannot be received, it is determined that the slave device does not support UHS-II, and the UHS-II initialization is stopped.

[7-3. effect]
According to the sixth embodiment of the present invention, when the LV-I slave device 720 is connected to the UHS-II host device 400, the UHS-II host device 400 fixes the CLK line 1813d and the DAT1 line 1812b. The LV-I slave device 720 cannot detect all the signals that are continuously at a low level on the VDD1, clock, and DAT1 line 1812b for a predetermined period. . At this time, the LV-I slave device 720 determines that the LV-I interface is not initialized, and does not drive the DAT2 line 1813a to a low level, and consequently does not transmit 0.

  If the UHS-II host device 400 drives the DAT2 line 1813a to the high level and transmits 1, the LV-I slave device 720 drives the DAT2 line 1813a to the low level and transmits 0. A signal collision occurs in which signals having different voltage levels are transmitted from both the device and the slave device, which adversely affects both semiconductor chips.

  However, when the LV-I slave device 720 in this embodiment determines that the LV-I interface is not initialized, it does not drive the DAT2 line 1813a to a low level, so the UHS-II host device 400 causes the DAT2 line 1813a. No matter what the state is, the above signal collision never occurs.

  In this embodiment, the CLK line 1813d is fixed at the low level, but the same effect can be obtained even when the UHS-II host device 400 fixes the CLK line 1813d at the high level.

  Although the present embodiment has been described on the assumption that the LV-I slave device 720 does not support UHS-II, the same effect can be obtained even when it supports it. At this time, the LV-I slave device 720 has terminals of a VDD2 line 1811, a D0 line 1814, and a D1 line 1815. The LV-I slave device 720 to which VDD2 which is 1.8V power is supplied via the VDD2 line 1811 is connected to the STB. When the L symbol 1903a is received, the STB. L symbol 1903b is transmitted. Thereafter, within a predetermined time T, STB. The UHS-II host apparatus 400 that has received the L symbol 1903b continues the UHS-II initialization (FIG. 20).

Note that, when the LV-I slave device in this embodiment has a function of receiving 1.8 V power supply via VDD2 as in the second embodiment, the LV-I semiconductor chip 721 is supplied by the VDD2 line 1811. However, the final result is the same.
[8. Addendum]
In the present disclosure, when an LV-I is newly introduced in addition to the legacy I / F and UHS-II which are existing interfaces between an SD card and a corresponding host device, an LV-I host device and an LV-I slave A method in which the apparatuses identify each other that the other party supports LV-I (Embodiments 1 and 2), and a method in which at least the existing host device and the existing slave device are not adversely affected (same as above) 3 to 6) have been described.

  As for the former, among the legacy host device, UHS-II host device, and LV-I host device, it is LV-I that supplies a low level signal on the VDD1, clock, and DAT1 lines immediately after power-on. Since it is limited to the host, the LV-I slave device can easily identify the LV-I host device, and the LV-I host device puts the DAT2 line in the Hi-Z state and pulls up when the power is turned on. The LV-I slave device can detect the LV-I slave device by driving the DAT2 line to a low level and transmitting 0 so that the LV-I host device can detect the LV-I slave device.

And for the latter,
(1) LV-I host device and legacy slave device (2) LV-I host device and UHS-II slave device (3) Legacy host device and LV-I slave device (4) UHS-II host device and LV-I Considering the four types of slave devices, the LV-I host device whose upper limit of the input signal withstand voltage is 1.8V does not receive the 3.3V signal, and the host device and the slave device are at different voltage levels. It was confirmed that the initialization was stopped without causing a signal collision to drive or that the initialization with the legacy I / F or UHS-II I / F was correctly executed.

  Further, as described in the fifth embodiment, the LV-I slave device of the present invention may be connected to a legacy host device. After startup, the legacy host device transmits an I / F condition check command with a 3.3V signal without detecting the characteristics of the connected slave device. Therefore, when the LV-I slave device of the present invention supports the legacy I / F, it goes without saying that the input signal withstand voltage of the LV-I semiconductor chip is 3.3 V or more even when the legacy LV is not supported. It is necessary.

  It is also possible to notify the LV-I host device that the LV-I slave device of the present invention supports LV-I using a specific signal line other than DAT2. Note that the UHS-II host device may drive 1 to transmit all signal lines of the DAT line and the CMD line. Therefore, as disclosed in the present invention, the LV-I slave device Only when connected to the LV-I host device, the method of transmitting 0 by driving the specific signal line to the low level is effective.

  The signal line used in the LV-I of the present invention is equivalent to the legacy I / F. Therefore, there is an effect that it is not necessary to increase the number of terminals of the LV-I semiconductor chip of the host device and the slave device.

  In the embodiment of the present invention, the voltage of the high voltage signal is 3.3 V and the voltage of the low voltage signal is 1.8 V. However, other voltage values may be used as long as the voltage magnitude relationship is maintained. But you can.

  In addition, the LV-I slave device of the present invention preferably includes a legacy I / F so that the legacy host device can operate. At this time, if the low-voltage signal voltage is 1.8 V, it becomes the same as the UHS-I mode signal voltage, and the mounting of the LV-I semiconductor chip becomes easy.

  In the embodiments described so far, the legacy slave device 120 assumes that the DAT0 line 113a immediately after startup is in the Hi-Z state. On the other hand, for the sake of implementation, there is a possibility that the legacy slave device 120 that has transmitted 1 by driving the DAT0 line 113a to the high level immediately after startup is already on the market. Such a legacy slave device 120 transmits a 3.3V signal to the host device via the DAT0 line 113a immediately after activation.

  At this time, if the connected host device is the LV-I host device 700 described so far, a 3.3 V signal is supplied to the host device I / F unit 704 whose upper limit of the input signal withstand voltage is 1.8 V, There is a possibility that the host device I / F unit 704 is destroyed.

  In order to avoid such a situation, as shown in FIG. 21, the DAT0 port 2101 of the host device I / F unit 704 of the LV-I host device 700 and the DAT0 line terminal 2103 of the slot 2102 in which the slave device 2105 is installed are connected. It is conceivable to provide a switch 2104 between them. The switch 2104 has a function of switching a DAT0 line, which is a predetermined signal line, between a non-conductive state (OFF) and a conductive state (ON) of the DAT0 line in a host device outside the host device I / F unit.

  The host device I / F unit 704 turns off the switch 2104 before performing initialization by LV-I, so that the DAT0 port 2101 and the DAT0 line terminal 2103 are not electrically connected.

  As shown in FIG. 7, when the LV-I slave device 720 is connected to the LV-I host device 700 as the slave device 2105, the LV-I host device 700 indicates that the DAT2 line is at a low level in 803 of FIG. Is detected, the connected slave device is recognized as the LV-I slave device 720. Thereafter, the host device I / F unit 704 turns on the switch 2104 to electrically connect the DAT0 port 2101 and the DAT0 line terminal 2103.

  Since the LV-I slave device 720 described here never transmits a 3.3V signal to the LV-I host device 700, the slave device attached at 803 in FIG. 8 is the LV-I slave device 720. Once it is detected, there is no problem even if the DAT0 line is connected. As shown in FIG. 9, the same effect can be obtained when both the LV-I host device 900 and the LV-I slave device 920 as the slave device 2105 have the VDD2 terminal.

  On the other hand, when the legacy slave device 120 is connected as the slave device 2105 to the LV-I host device 700 as shown in FIG. 11, the host device does not detect that the DAT2 line is at the low level as shown in FIG. This means that the connected slave device does not support LV-I, and as a result, the LV-I host device 700 does not perform initialization. At this time, if the switch 2104 remains OFF, even if the legacy slave device 120 drives DAT0 to a high level and transmits 1, the host device I / F unit 704 of the LV-I host device 700 has 3 .3V signals are not received. At this time, since the LV-I host device 700 does not perform initialization, there is no problem as a result even if the switch 2104 is left OFF.

  The same effect can be obtained even if the attached slave device is a UHS-II slave device 420 that does not support LV-I.

  The present disclosure can be applied to a slave device including an SD card, a corresponding host device, and a removable system including the host device and the slave device.

100 Legacy Host Device 101 Power Supply Unit 102 Legacy I / F Semiconductor Chip 103 I / F Signal Regulator 104 Host Device I / F Unit 105 I / F Control Unit 110 VDD1 Line 111 CLK Line 112 CMD Line 113 DAT Line 113a DAT0 Line 113b DAT1 line 113c DAT2 line 113d DAT3 line 120 Legacy slave device 121 Legacy I / F semiconductor chip 122 I / F signal regulator 123 Slave device I / F unit 124 I / F control unit 125 Back-end module 200 Reset command 201a I / F condition Check command 201b Response 202a Initialization command 202b Response 203a Write command 203b Response 203c 301a Voltage switching command 301b Response 400 UHS-II host device 401 First power supply unit 402 Second power supply unit 403 UHS-II semiconductor chip 404 I / F signal regulator 405 Host device I / F unit 406 I / F control Unit 410 VDD1 line 411 VDD2 line 412 RCLK line 413 D0 line 414 D1 line 420 UHS-II slave device 421 UHS-II semiconductor chip 422 I / F signal regulator 423 Slave device I / F unit 424 I / F control unit 425 Back end Module 501a STB. L symbol 501b STB. L symbol 502a Initialization command 502b Response 503a Write command 503b Response 503c Data 600 LV-I host device 601 Power supply unit 602 LV-I semiconductor chip 603 I / F signal regulator 604 Host device I / F unit 605 I / F control unit 700 LV-I Host Device 701 Power Supply Unit 702 LV-I Semiconductor Chip 703 I / F Signal Regulator 704 Host Device I / F Unit 705 I / F Control Unit 710 VDD1 Line 711 CLK Line 712 CMD Line 713 DAT Line 713a DAT0 Line 713b DAT1 line 713c DAT2 line 713d DAT3 line 720 LV-I slave device 721 LV-I semiconductor chip 722 I / F signal regulator 723 Slave device I / F unit 724 I / F control unit 725 Backend module 806 Reset command 807a I / F condition check command 807b Response 808 Data 900 LV-I host device 901 First power supply unit 902 Second power supply unit 903 LV -I Semiconductor chip 904 Host device I / F unit 905 I / F control unit 910 VDD1 line 911 VDD2 line 912 CLK line 913 CMD line 914 DAT line 914a DAT0 line 914b DAT1 line 914c DAT2 line 914d DAT3 line 920LV 921 LV-I semiconductor chip 922 VDD1 detection unit 923 Slave device I / F unit 924 I / F control unit 925 Backend module 1110 VDD1 1111 CLK line 1112 CMD line 1113 DAT line 1113a DAT0 line 1113b DAT1 line 1113c DAT2 line 1113d DAT3 line 1310 VDD1 line 1311 CLK line 1312 CMD line 1313 DAT line 1313a DAT13 line 1313bD13 line 1313a DAT13 line CLK line 1512 CMD line 1513 DAT line 1513a DAT0 line 1513b DAT1 line 1513c DAT2 line 1513d DAT3 line 1603 Reset command 1604a I / F condition check command 1604b Response 1810 VDD1 line 1811 VD 2 line 1812 RCLK line 1812a DAT0 line 1812b DAT1 line 1813a DAT2 line 1813B DAT3 line 1813C CMD line 1813D CLK line 1814 D0 line 1815 D1 line 1903a STB. L symbol 1903b STB. L symbol 2101 DAT0 port 2102 slot 2103 DAT0 line terminal 2104 switch 2105 slave device

Claims (17)

A host device that can be connected to a slave device through a plurality of interfaces having different voltage levels,
A power supply for supplying power to the slave device;
A clock signal transmitter for transmitting a clock signal to the slave device;
A transmitter for transmitting a first signal to the slave device;
Receiving a second signal from the slave device,
Supply power from the power supply unit,
From the clock signal transmission unit, transmit the clock signal,
The transmitter transmits 0 as the first signal,
The host device stops transmission of 0 as the first signal when the receiving unit receives 0 as the second signal.   The transmission device transmits a command signal to the slave device when the reception unit receives a non-zero signal as the second signal after stopping transmission of the first signal as the first signal. The host device according to 1.   2. The host device according to claim 1, wherein when the receiving unit does not receive 0 as the second signal, a command signal is not transmitted to the slave device. 3.   In the host device, before supplying power from the power supply unit, a predetermined signal line is set in a non-conductive state, and when a command signal is transmitted to the slave device, the predetermined signal line is set in a conductive state. The host device according to claim 2, wherein:   The host device according to claim 4, wherein the first signal and the second signal are not communicated via the predetermined signal line.   The host device according to claim 1, wherein the voltage level of the interface is 3.3 V and 1.8 V, and communication is possible only with the interface having the voltage level of 1.8 V. Pull up the first signal and the second signal at 1.8V,
The host device according to claim 6, wherein at least the second signal is released before power is supplied from the power supply unit. A slave device that can be connected to a host device through a plurality of interfaces having different voltage levels,
A power supply unit to which power is supplied from the host device;
A clock signal receiver for receiving a clock signal from the host device;
A receiver for receiving a first signal from the host device;
A transmission unit for transmitting a second signal to the host device,
In the power supply unit, the power is supplied,
And the clock signal receiving unit receives the clock signal,
And when the receiving unit receives 0 as the first signal,
The slave device transmits 0 as the second signal from the transmission unit.   The transmission of 0 as the second signal is stopped when the receiving unit receives a non-zero signal as the first signal after transmitting 0 as the second signal. Item 9. The slave device according to Item 8. A regulator for changing a voltage level of the power source supplied from the power supply unit;
After transmitting 0 as the second signal, the receiving unit receives a non-zero signal as the first signal, and when the activation of the regulator is completed, the second signal is zero. 9. The slave device according to claim 8, wherein transmission is stopped. When the power is not supplied at the power supply unit,
Or when the clock signal receiving unit does not receive the clock,
Or when the receiving unit does not receive 0 as the first signal,
The slave device according to claim 8, wherein the transmission unit does not transmit 0 as the second signal.   9. The slave device according to claim 8, wherein the voltage level of the interface is 3.3V and 1.8V, and communication is possible with the interface having at least the voltage level of 1.8V.   13. The slave device according to claim 12, wherein at least the first signal is released before power is supplied from the power supply unit. A removable system consisting of a host device and a slave device connected by a plurality of interfaces having different voltage levels,
When the host apparatus supplies power to the slave apparatus, transmits a clock signal, and transmits 0 as a first signal, the slave apparatus transmits a second signal to the host apparatus. Send 0,
When the host device receives 0 as the second signal, it stops transmitting 0 as the first signal,
When the slave device receives a non-zero signal as the first signal, the slave device stops transmitting 0 as the second signal;
The removable system according to claim 1, wherein the host device transmits a command signal to the slave device when receiving a non-zero signal as the second signal. The slave device further includes a regulator,
The slave device stops transmission of 0 as the second signal when the activation of the regulator is completed and a signal that is not 0 is received as the first signal. The removable system according to claim 14.   In the host device, before supplying power, a predetermined signal line is set in a non-conductive state, and when a command signal is transmitted to the slave device, the predetermined signal line is set in a conductive state. The removable system according to claim 14 or 15.   The removable system according to claim 16, wherein the first signal and the second signal are not communicated via the predetermined signal line.

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