VTUSD016GCCDMTLN

US Headquarters 2950 Red Hill Ave, Costa Mesa California, USA 92626 Office: 714.913.2200 Fax: 714.913.2202 www.vikingtechnology.com Datasheet for: Industrial SDHC microSD Card PSUSDxxxxCxxxxxN microSD Cards for Industrial Applications Legal Information Copyright© 2017 Sanmina Corporation. All rights reserved. The information in this document is proprietary and confidential to Sanmina Corporation. No part of this document may be reproduced in any form or by any means or used to make any derivative work (such as translation, transformation, or adaptation) without written permission from Sanmina. Sanmina reserves the right to revise this documentation and to make changes in content from time to time without obligation on the part of Sanmina to provide notification of such revision or change. Sanmina provides this documentation without warranty, term or condition of any kind, either expressed or implied, including, but not limited to, expressed and implied warranties of merchantability, fitness for a particular purpose, and non-infringement. While the information contained herein is believed to be accurate, such information is preliminary, and should not be relied upon for accuracy or completeness, and no representations or warranties of accuracy or completeness are made. In no event will Sanmina be liable for damages arising directly or indirectly from any use of or reliance upon the information contained in this document. Sanmina may make improvements or changes in the product(s) and/or the program(s) described in this documentation at any time. Sanmina, Viking Technology, Viking Modular Solutions, and the Viking logo are trademarks of Sanmina Corporation. Other company, product or service names mentioned herein may be trademarks or service marks of their respective owners. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 2 Revision History Date 4/17/17 Revision A Description Initial release. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Checked by Industrial SDHC microSD Cards Page 3 Ordering Information for the Industrial SDHC microSD Card VikingPart# Interface Temp GB Application NAND VTUSD8192CCWMTLN microSD Card (-30 to +85'c) 8GB (SDHC) Industrial TSB 15nm MLC VTUSD016GCCDMTLN VTUSD032GCCBMTLN microSD Card microSD Card (-30 to +85'c) (-30 to +85'c) 16GB (SDHC) 32GB (SDHC) Industrial Industrial TSB 15nm MLC TSB 15nm MLC Notes: 1. Contact Viking for availability date 2. The lowercase letters x,y and z are wildcard characters that indicate product or customer specific information 3. Refer to the Viking part number coversheet or PN decoder for details. 4. Based on FLASH Industrial SD 3.0 Toshiba MLC NAND SDHC Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 4 Table of Contents 1 INTRODUCTION 8 1.1 FEATURES 8 2 MICROSD CARD STANDARDS COMPATIBILITY 9 3 PHYSICAL CHARACTERISTICS 9 3.1 Package Characteristics 9 3.2 Environmental Characteristics 9 3.3 Physical Characteristics 10 4 ELECTRICAL INTERFACE 10 4.1 Pin Assignment 10 4.2 Contact Pad Thickness 11 4.3 Table 4-2: microSD Card Contact Pad Thickness 11 4.4 microSD Card Bus Topology 4.4.1 SD Bus Mode protocol 11 11 4.5 17 SDHC Card Initialization 4.6 Electrical Characteristics 4.6.1 Absolute Maximum Conditions 4.6.2 DC Characteristics 4.6.3 AC Characteristics (Default Speed) 4.6.1 AC Characteristics (High Speed) 4.6.2 AC Characteristics (SDR104, SDR50, SDR25, SDR12) 21 21 22 24 26 27 5 CARD INTERNAL INFORMATION 31 5.1 Security Information 31 5.2 microSD Card Registers 5.2.1 OCR Register 5.2.2 CID Register 5.2.3 CSD Register 5.2.4 RCA Register 5.2.5 DSR Register 5.2.6 SCR Register 5.2.7 Card Status 5.2.8 SD Status Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 31 32 33 33 35 35 35 35 37 Industrial SDHC microSD Cards Page 5 5.2.9 Switch Function Status 38 5.3 Logical Format 5.3.1 microSD Card Capacities 5.3.2 microSD card System Information 5.3.3 Data of the logical format of a 8GB Card 5.3.4 Data of the logical format of a 16GB Card 5.3.5 Data of the logical format of a 32GB Card 39 40 40 40 40 40 6 SD SPECIFICATION COMPLIANCE 40 7 RELIABILITY GUIDANCE 41 8 MICROSD CARD MECHANICAL DIMENSIONS 43 Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 6 Table of Tables Table 1-1: Features ___________________________________________________________________ 8 Table 1-2: Summary of Industrial Features _________________________________________________ 8 Table 4-1: microSD Card Pin Assignment ________________________________________________ 10 4.3 Table 4-2: microSD Card Contact Pad Thickness ____________________________________ 11 Table 4-3: SD Mode Command Set ( + = Implemented, - = Not Implemented) __________________ 12 Table 4-4: SPI Mode Command Set ( + = Implemented, - = Not Implemented) _________________ 15 Table 4-5:S18R and S18A Combinations _________________________________________________ 19 Table 4-6: Absolute Maximum Conditions ________________________________________________ 21 Table 4-7: DC Characteristics Threshold level for High Voltage Range) _________________________ 22 Table 4-8: Peak Voltage and Leakage Current_____________________________________________ 22 Table 4-9: DC Characteristics (Threshold level for 1.8V signaling) _____________________________ 22 Table 4-10: Input Leakage Current for 1.8V Signaling _______________________________________ 23 Table 4-11: Power Consumption _______________________________________________________ 23 Table 4-12: Signal Capacitance ________________________________________________________ 24 Table 4-13: AC Characteristics (Default Speed) ____________________________________________ 25 Table 4-14: AC Characteristics (High Speed) ______________________________________________ 26 Table 4-15: Clock Signal Timing of SDR104, SDR50, SDR25, SDR12 modes input _______________ 27 Table 4-16: Clock input Timing of SDR104, SDR50, SDR25, SDR12 input timing _________________ 28 Table 4-17: Output Timing of Fixed Data Window ( SDR50, SDR25, SDR12 ) ____________________ 28 Table 4-18: Output Timing of Variable Data Window ( SDR104 ) ______________________________ 29 Table 4-19: Clock Signal Timing of DDR50 _______________________________________________ 30 Table 4-20: BUS Timings – Parameters Values (DDR50 mode) _______________________________ 30 Table 5-1: microSD Card Registers _____________________________________________________ 32 Table 5-2: OCR Register Definition _____________________________________________________ 32 Table 5-3: CID register _______________________________________________________________ 33 Table 5-4: CSD register ______________________________________________________________ 33 Table 5-5: The SCR Fields ____________________________________________________________ 35 Table 5-6: Card Status _______________________________________________________________ 35 Table 5-7: SD Status _________________________________________________________________ 37 Table 5-8: Switch Function Status ______________________________________________________ 38 Table 5-9: microSD Card Capacities ____________________________________________________ 40 Table 5-10: microSD Card System information ____________________________________________ 40 Table of Figures Figure 1-1: Top View __________________________________________________________________ 9 Figure 4-1: microSD Card Pin Assignment (Back view of the Card) ____________________________ 10 Figure 4-2: Bus Connection Diagram (SD Mode) ___________________________________________ 12 Figure 4-3: Bus Connection Diagram (SPI Mode) __________________________________________ 15 Figure 4-4: UHS-I Host Initialization Flow Chart ____________________________________________ 17 Figure 4-5: ACMD41 Timing Followed by Signal Voltage Switch Sequence ______________________ 18 Figure 4-6: Signal Voltage Switch Sequence ______________________________________________ 20 Figure 4-7: microSD Card Connection Diagram ____________________________________________ 21 Figure 4-8: AC Timing Diagram (Default Speed Mode) ______________________________________ 24 Figure 4-9: AC Timing Diagram (High Speed Mode) ________________________________________ 26 Figure 4-10: AC Timing Diagram (SDR104, SDR50, SDR25, SDR12 modes input) ________________ 27 Figure 4-11: AC Timing Diagram (SDR104, SDR50, SDR25, SDR12 input timing)_________________ 27 Figure 4-12: Output Timing of Fixed Window ______________________________________________ 28 Figure 4-13: Output Timing of Variable Window ____________________________________________ 29 Figure 4-14: Clock Signal Timing _______________________________________________________ 29 Figure 4-15: Timing Diagram DAT Inputs/Outputs Referenced to CLK in DDR50 Mode _____________ 30 Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 7 1 Introduction This data sheet describes the specifications of the SDHC microCard, a Memory Card of Small and Thin with SDMI compliant Security method. (SDMI: Secure Digital Music Initiative) Contents in the Card can be protected by CPRM based security. This contents security can be accomplished by SDHC microCard, host, and security application software combinations. 1.1 FEATURES Table 1-1: Features Media Format microSD Memory Card Standard Security Functions Logical Format Electrical Features Operating Voltage Operating Current SD Interface Physical Features Compliant with the SD Memory Card Standard Ver. 4.20, UHS104 SD Security Specification Ver.2.00 Compliant (CPRM Based) *CPRM: Contents Protection for Recording Media Specification SD File System Specification Ver.2.00 Compliant SDHC Card = FAT32 VDD = 2.7V(min), 3.3V(Typ), 3.6V(max) SDR104 Write : 140mA(max) SDR104 Read : 150mA(max) DS : Signaling Voltage = 3.3V(Typ), SDCLK = 25MHz HS : Signaling Voltage = 3.3V(Typ), SDCLK = 50MHz Physical Package size /Mass L: 15, W: 11, T: 1 (mm), Weight: 0.3g (typ.) SD Physical Layer Specification Ver.3.01 Compliant Durability RoHS Compliant with SD Physical Layer Specification Ver.3.01 and microSD Memory Card specification 2.01 Compliant Compliant with RoHS regulations (DIRECTIVE 2011/65/EU) Table 1-2: Summary of Industrial Features 1. Operating temperature: -30 to + 85°C 2. Contact Pad Foundation Material Ni 0.5µm Thickness Surface Material Au 0.3µm Thickness Material Foundation Ni Surface Au Thickness 0.5µm 0.3µm 3. The status of Device Health can be checked by the host using CMD56 Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 8 Figure 1-1: Top View 2 microSD Card Standards Compatibility This microSD Memory Card Specification is compliant with:     PHYSICAL LAYER SPECIFICATION Ver.3.01 (Part1) (Except for Mechanical Specification) FILE SYSTEM SPECIFICATION Ver.2.00. (Part2) SECURITY SPECIFICATION Ver.2.00. (Part3) microSD Card Memory Card Specification Version 2.01 3 Physical Characteristics 3.1 Package Characteristics 1. Mold Material: Epoxy Resin+Silicon Dioxide 2. Flameproof Grade: V-0(UL94) 3. Heatproof Temperature: approx.400 degrees 3.2 Environmental Characteristics The standard Operation Conditions are:  Absolute Maximum Temperature Range  Humidity less than RH = 95 %, Non condensed Ta = -30 to +85°C Ta = 25°C The standard Storage Conditions are: Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 9   Maximum Temperature Range: Humidity less than RH = 93%, Non condensed Tstg = -40 to +85°C Ta = 40°C 3.3 Physical Characteristics 1) Hot Insertion or Removal The microSD Card can be removed or inserted without power off from the host system as described in the SD Physical Layer Specification 6.1 The connector will recognize the Hot Insertion or Removal is defined in the 6.2 of the PHYSICAL LAYER SPECIFICATION. 2) Mechanical Write Protect Switch The microSD memory Card has no mechanical write protect switch. 4 Electrical Interface 4.1 Pin Assignment The table below describes the pin assignment of the microSD card. The following figure describes the pin assignment of the microSD card. Please refer to the detail descriptions by SD Card Physical Layer Specification. Figure 4-1: microSD Card Pin Assignment (Back view of the Card) Table 4-1: microSD Card Pin Assignment SD Mode SPI Mode Pin Name IO Type Description Name IO Type Description 1 DAT2 I/O/PP Data Line[Bit2] RSV I/O/ PP Card Detect/ Data Line[Bit3] CS I PP Command/Response DI I Chip Select (Negative True) Data In 3 CD/ DAT3 CMD 4 VDD S Supply Voltage VDD S Supply Voltage 5 CLK I Clock SCLK I Clock 2 Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 10 SD Mode SPI Mode Pin Name IO Type Description Name IO Type Description 6 VSS S Ground VSS S Ground 7 DAT0 I/O/PP Data Line[Bit0] DO O/PP Data Out 8 DAT1 I/O/PP Data Line[Bit1] RSV － Notes: S: Power Supply I: Input O: Output using push-pull drivers PP: I/O using push-pull drivers (*) These signals should be pulled up by host side with 10-100k ohm resistance in the SPI Mode. Reserved(*) 4.2 Contact Pad Thickness 4.3 Table 4-2: microSD Card Contact Pad Thickness Foundation Surface Material Ni Au Thickness 0.5µm 0.3µm 4.4 microSD Card Bus Topology The device supports two alternative communication protocols: SD and SPI Bus Mode. It is as same as standard microSD memory cards. Host System can choose either one of modes. Same Data of the device can read and write by both modes. SD Mode allows the 4-bit high performance data transfer. SPI Mode allows easy and common interface for SPI channel. The disadvantage of this mode is loss of performance, relatively to the SD mode. 4.4.1 SD Bus Mode protocol The SD bus allows the dynamic configuration of the number of data line from 1 to 4 Bidirectional data signal. After power up by default, the Device will use only DAT0. After initialization, host can change the bus width. Multiplied microSD cards connections are available to the host. Common VDD, VSS and CLK signal connections are available in the multiple connections. However, Command, Respond and Data lined (DAT0-DAT3) shall be divided for each card from host. This feature allows easy tradeoff between hardware cost and system performance. Communication over the SD bus is based on command and data bit stream initiated by a start bit and terminated by stop bit. Command: Commands are transferred serially on the CMD line. A command is a token to starts an operation from host to the card. Commands are sent to an addressed single card (addressed Command) or to all connected cards (Broad cast command). Response: Responses are transferred serially on the CMD line. A response is a token to answer to a previous received command. Responses are sent from an addressed single card or from all connected cards. Data: Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 11 Data can be transfer from the card to the host or vice versa. Data is transferred via the data lines. microSD Card (A) microSD Card (B) Figure 4-2: Bus Connection Diagram (SD Mode) CLK CMD DAT0 - DAT3 VDD VSS Host card Clock signal Bi-directional Command/ Response Signal 4 Bi-directional data signal Power supply GND Table 4-3: SD Mode Command Set ( + = Implemented, - = Not Implemented) CMD Index Abbreviation CMD0 GO_IDLE_STATE + CMD2 ALL_SEND_CID + CMD3 SEND_RELATIVE_ADDR + CMD4 SET_DSR - CMD6 SWITCH_FUNC + CMD7 SELECT/DESELECT_CARD + CMD8 SEND_IF_COND + CMD9 SEND_CSD + Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Implementation Note DSR Register is not implemented. Industrial SDHC microSD Cards Page 12 CMD Index Abbreviation Implementation Note CMD10 SEND_CID + CMD11 VOLTAGE_SWITCH + CMD12 STOP_TRANSMISSION + CMD13 SEND_STATUS + CMD15 GO_INACTIVE_STATE + CMD16 SET_BLOCKLEN + CMD17 READ_SINGLE_BLOCK + CMD18 READ_MULTIPLE_BLOCK + CMD19 SEND_TUNING_PATTERN + UHS-I mode CMD20 SPEED_CLASS_CONTROL + For SDHC/SDXC CMD23 SET_BLOCK_COUNT + CMD24 WRITE_BLOCK + CMD25 WRITE_MULTIPLE_BLOCK + CMD26 Reserved for Manufacturer + CMD27 PROGRAM_CSD + CMD28 SET_WRITE_PROT - CMD29 CLR_WRITE_PROT - CMD30 SEND_WRITE_PROT - CMD32 ERASE_WR_BLK_START + CMD33 ERASE_WR_BLK_END + CMD38 ERASE + CMD42 LOCK_UNLOCK + CMD55 APP_CMD + CMD56 GEN_CMD + CMD60 Reserved for Manufacturer + CMD61 Reserved for Manufacturer + CMD62 Reserved for Manufacturer + ACMD6 SET_BUS_WIDTH + ACMD13 SD_STATUS + ACMD22 SEND_NUM_WR_BLOCKS + ACMD23 SET_WR_BLK_ERASE_COUNT + ACMD41 SD_APP_OP_COND + ACMD42 SET_CLR_CARD_DETECT + ACMD51 SEND_SCR + ACMD18 SECURE_READ_MULTI_BLOCK + ACMD25 SECURE_WRITE_MULTI_BLOCK + ACMD26 SECURE_WRITE_MKB + ACMD38 SECURE_ERASE + ACMD43 GET_MKB + ACMD44 GET_MID + ACMD45 SET_CER_RN1 + ACMD46 GET_CER_RN2 + ACMD47 SET_CER_RES2 + Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 UHS-I mode Internal Write Protection is not implemented. This command is the status of Device Health that can be checked by the host Industrial SDHC microSD Cards Page 13 CMD Index Abbreviation Implementation Note ACMD48 GET_CER_RES1 + ACMD49 CHANGE_SECURE_AREA + Notes:  CMD28, 29 and CMD30 are optional commands.  CMD4 is not implemented because DSR register (Optional Register) is not implemented.  CMD56 is a vender specific command which is not defined in the standard card. For this product, this command gets the Device Health so that the status of Device Health can be checked by the host 6.2.2 SPI Bus mode Protocol The SPI bus allows 1 bit Data line by 2-chanel (Data In and Out). The SPI compatible mode allows the MMC Host systems to use microSD card with little change. The SPI bus mode protocol is byte transfers. All the data token are multiples of the bytes (8-bit) and always byte aligned to the CS signal. The advantage of the SPI mode is reducing the host design effort. Especially, the MMC host can be modified with little change. The disadvantage of the SPI mode is the loss of performance versus SD mode. Caution: Please use SD Card Specification. DO NOT use MMC Specification. (For example, initialization is achieved by ACMD41, and be careful to Register. Register definition is different, especially CSD Register.) Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 14 microSD Card (A) microSD Card (B) Figure 4-3: Bus Connection Diagram (SPI Mode) CS CLK CMD DataIN DataOUT VDD VSS Card Select Signal Host card Clock signal Bi-directional Command/ Response Signal Host to card data line Host to card data line Power supply GND Table 4-4: SPI Mode Command Set ( + = Implemented, - = Not Implemented) CMD Index Abbreviation Implementation Note CMD0 GO_IDLE_STATE + CMD1 SEND_OP_COND + CMD6 SWITCH_FUNC + CMD8 SEND_IF_COND + CMD9 SEND_CSD + CMD10 SEND_CID + CMD12 STOP_TRANSMISSION + Note: DO NOT USE (See UHS-I Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Host Initialization Flow Chart and the section called “Efficient Data Writing to SD Memory Card” Industrial SDHC microSD Cards Page 15 CMD Index Abbreviation Implementation Note CMD13 SEND_STATUS + CMD16 SET_BLOCKLEN + CMD17 READ_SINGLE_BLOCK + CMD18 READ_MULTIPLE_BLOCK + CMD24 WRITE_BLOCK + CMD25 WRITE_MULTIPLE_BLOCK + CMD26 Reserved for Manufacturer + CMD27 PROGRAM_CSD + CMD28 SET_WRITE_PROT - CMD29 CLR_WRITE_PROT - CMD30 SEND_WRITE_PROT - CMD32 ERASE_WR_BLK_START + CMD33 ERASE_WR_BLK_END + CMD38 ERASE + CMD42 LOCK_UNLOCK + CMD55 APP_CMD + CMD56 GEN_CMD + CMD58 READ_OCR + CMD59 CRC_ON_OFF + CMD60 Reserved for Manufacturer + ACMD13 SD_STATUS + ACMD22 SEND_NUM_WR_BLOCKS + ACMD23 SET_WR_BLK_ERASE_COUNT + ACMD41 SD_APP_OP_COND + ACMD42 SET_CLR_CARD_DETECT + ACMD51 SEND_SCR + ACMD18 SECURE_READ_MULTI_BLOCK + ACMD25 SECURE_WRITE_MULTI_BLOCK + ACMD26 SECURE_WRITE_MKB + ACMD38 SECURE_ERASE + ACMD43 GET_MKB + ACMD44 GET_MID + ACMD45 SET_CER_RN1 + ACMD46 GET_CER_RN2 + ACMD47 SET_CER_RES2 + ACMD48 GET_CER_RES1 + Internal Write Protection is not implemented. This command is not specified. ACMD49 CHANGE_SECURE_AREA + Notes:  CMD28, CMD29 and CMD30 are optional commands.  CMD56 is a vender specific command which is not defined in the standard card. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 16 4.5 SDHC Card Initialization The flow chart for UHS-I hosts and the sequence of commands to perform a signal voltage switch is shown below. Red and yellow boxes are new procedures to initialize the UHS-I card. Figure 4-4: UHS-I Host Initialization Flow Chart Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 17 Figure 4-5: ACMD41 Timing Followed by Signal Voltage Switch Sequence 1) POWER ON: Supply Voltage for initialization. Host System applies the perating Voltage to the card. Apply more than 74 cycles of Dummy-clock to the microSD card. 2) Select operation mode (SD mode or SPI mode) In the case of SPI mode operation, the host should drive pin 1 (CD/DAT3) of the microSD Card I/F to a “Low” level. Then, issue CMD0. In the case of SD mode operation, the host should drive or detect pin 1 of the microSD Card I/F (Pull up register of pin 1 is pull up to “High” normally). The card maintains selected operation mode except re-issue of CMD0 or power on below is SD mode initialization procedure. 3) Send Interface condition command (CMD8). When the card is in the Idle state, the host shall issue CMD8 before ACMD41. In the argument, 'voltage supplied' is set to the host supply voltage and 'check pattern' is set to any 8-bit pattern. The card that accepted the supplied voltage returns R7 response. In the response, the card echoes back both the voltage range and check pattern set in the argument. If the card does not support the host supply voltage, it shall not return response and stays in the Idle state. 4) Send initialization command (ACMD41). When the signaling level is 3.3V, the host repeats an issue ACMD41 with HCS=1 and S18R=1 until the response indicates ready. The argument (HCS and S18R) of the first ACMD41 is effective but the all the following ACMD41 should be issued with the same argument. If Bit 31 indicates ready, the host needs to check CCS and S18A. The card indicates S18A=0, which means that the voltage switch is not allowed and the host needs to use the current signaling level. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 18 Table 4-5:S18R and S18A Combinations Current Signaling Level 18R S18A Comment 0 0 1.8V signaling is not requested 3.3V 1 0 The card does not support 1.8V signaling 1 1 Start signal voltage switch sequence 1.8V X 0 Already switched to 1.8V 5) Send voltage switch command (CMD11) S18A=1 means that the voltage switch is allowed and host issues CMD11 to invoke voltage switch sequence. By receiving CMD11, the card returns R1 response and start voltage switch sequence. No response of CMD11 means that S18A was 0 and therefore the host should not have sent CMD11. Completion of voltage switch sequence is checked by high level of DAT[3:0]. Any bit of DAT[3:0] can be checked depends on ability of the host. The card enters UHS-I mode and card input and output timings are changed (SDR12 in default) when the voltage switch sequence is completed successfully. 6) Send ALL_SEND_CID command (CMD2) and get the Card ID (CID) 7) Send SEND_RELATIVE_ADDR (CMD3) and get the RCA. RCA value is randomly changed by access, not equal zero. 8) Send SELECT / DESELECT_CARD command (CMD7) and move to the transfer state. When entering tran state, CARD_IS_LOCKED status in the R1 response should be checked (it is indicated in the response of CMD7). If the CARD_IS_LOCKED status is set to 1 in the response of CMD7, CMD42 is required before ACMD6 tounlock the card. ( If the card is locked, CMD42 is required to unlock the card. ) If the card is unlocked, CMD42 can be skipped. 9) Send SET_BUS_WIDTH command (ACMD6). UHS-I supports only 4-bit mode. Host shall select 4-bit mode by ACMD6. If the card is locked, host needs to unlock the card by CMD42 in 1-bit mode and then needs to issue ACMD6 to change 4-bit bus mode. Operating in 1-bit mode is not assured. 10) Set driver strength. CMD6 mode 0 is used to query which functions the card supports, and to identify the maximum current consumption of the card under the selected functions. In case of UHS-I card, appropriate driver strength (default is Type-B buffer) is selected by CMD6 Function Group 3. 11) Set UHS-I mode current limit. UHS-I modes ( Bus Speed Mode ) is selected by CMD6 Function Group 1. Current limit is selected by CMD6 Function Group 4. Note: Function Group 4 is defined as Current Limit switch for SDR50, SDR104, DDR50. The Current Limit does not act on the card in SDR12 and SDR25. The default value of the Current Limit is 200mA (minimum setting). Then after selecting one of SDR50, SDR104, DDR50 mode by Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 19 Function Group 1, host needs to change the Current Limit to enable the card to operate in higher performance. This value is determined by a host power supply capability to the card, heat release method taken by a host and the maximum current of a connector. 12) Tuning of sampling point CMD19 sends a tuning block to the host to determine sampling point. In SDR50, SDR104 and DDR50 modes, if tuning of sampling point is required, CMD19 is repeatedly issued until tuning is completed. Then the Host can access the Data between the microSD card as a storage device. Application Notes: 1.The host shall set ACMD41 timeout to more than 1 second to abort repeat of issuing ACMD41 when the card does not indicate ready. The timeout count starts from the first ACMD41 which is set voltage window in the argument. 2.Once the signal voltage is switched to 1.8V, the card continues 1.8V signaling regardless of CMD0. Power cycle resets the signal voltage to 3.3V. After switching 1.8V singling, the card cannot be changed to SPI mode. 3.Timing to Switch Signal Voltage To change signaling level at the same time between host and card, signal voltage switch sequence is invoked by CMD11 as shown in the figure below. CMD11 is issued only when S18A=1 in the response of ACMD41. Figure 4-6: Signal Voltage Switch Sequence Steps that the host takes to start a voltage switch sequence. 1. The host issues CMD11 to start voltage switch sequence. 2. The card returns R1 response. 3. The card drives CMD and DAT[3:0] to “low” immediately after the response. 4. The host stops supplying SDCLK. The card shall start switching voltage after host stops SDCLK. The time to stop SDCLK is not specified. The host can detect whether the sequence starts by checking signal level of either one of CMD, DAT[3:0]. What signal should be checked will depend on the ability of the host. If low level is not detected, the host should abort the sequence and execute power cycle. 5. 1.8V output of voltage regulator in card shall be stable within 5ms.The Host keeps SDCLK low at least 5ms. This means that 5ms is the maximum for the card and the minimum for the host. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 20 6. After 5ms from (step 4) and host voltage regulator is stable, the host starts providing SDCLK at 1.8V. The card can check whether SDCLK voltage is 1.8V. 7. By detecting SDCLK, the card drives CMD to high at 1.8V for at least one clock and then stops driving (tri-state). CMD is triggered by rising edge of SDCLK (SDR timing). 8. The card can check whether host drives CMD to 1.8V through the host pull-up resister. 9. If switching to 1.8V signaling is completed successfully, the card drives DAT[3:0] to high at 1.8V at least one clock and then stop driving (tri-state). DAT[3:0] is triggered by rising edge of SDCLK (SDR timing). DAT[3:0] shall be high within 1ms from start of providing SDCLK. Host check whether DAT[3:0] is high after 1ms from supplying SDCLK. This means that 1ms is the maximum for the card and the minimum for the host. 4.6 Electrical Characteristics Figure 4-7: microSD Card Connection Diagram 4.6.1 Absolute Maximum Conditions Table 4-6: Absolute Maximum Conditions Item Symbol Value Unit Supply Voltage Input Voltage VDD -0.3 to 3.9 V VIN -0.3 to VDD+0.3 (≤3.9) V Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 21 4.6.2 DC Characteristics Table 4-7: DC Characteristics Threshold level for High Voltage Range) Item Symbol Condition Supply Voltage MIN. Typ. VDD - 2.7 - High Level VIH - VDD* 0.625 - Low Level VIL - VSS0.3 - MAX. Unit 3.6 V VDD+0.3 V VDD*0.25 V - V Note Input Voltage High Level VOH VDD = Min VDD* IOH = -2mA 0.75 - Low Level VOL VDD = Min IOL= 2mA - - - - OutputVoltage Input Voltage SetupTime Vrs - VDD*0.125 V 250 ms From 0V to VDDMIn Table 4-8: Peak Voltage and Leakage Current Parameter Symbol Peak voltage on all lines Min Max. Unit -0.3 VDD+0.3 V -10 10 uA -10 10 uA Remarks All Inputs Input Leakage Current All Outputs Output Leakage Current Table 4-9: DC Characteristics (Threshold level for 1.8V signaling) Item Symbol MIN. MAX. Unit Supply Voltage VDD 2.7 3.6 V Regulator Voltage VDDIO 1.7 1.95 V High Level VIH 1.27 2.00 V Low Level VIL Vss-0.3 0.58 V High Level VOH 1.4 - V IOH=2mA Low Level VOL - 0.45 V IOL=2mA Input Voltage Output Voltage Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Condition Generated by VDD Industrial SDHC microSD Cards Page 22 Table 4-10: Input Leakage Current for 1.8V Signaling Parameter Symbol Input Leakage Current Min Max. -2 2 Unit Remarks uA DAT3 pull-up is disconnected Table 4-11: Power Consumption Item Symbol Standby Current Operation Current(peak) Condition ICCS 3.6V Clock Stop MIN. Typ. MAX. Unit - - 950 CurrentLimit=400mA VDD = 3.6V - - 300 ICCOP1 Current Limit=200mA *1) VDD = 3.6V - - 300 mA @25 deg C (HS or DS),VDD = 3.6V 300 Current Limit=400mA VDD = 3.6V 250 Current Limit=200mA Operation ICCOP2 VDD = 3.6V Current(average) *2) SDR25 or HS VDD = 3.6V 200 Vrs - @25 deg C mA @25 deg C 200 SDR12 or DS, VDD = 3.6V Input Voltage SetupTime uA Note 100 - - 250 ms From 0V to VDDMIn *1) Peak Current: RMS value over a 10usec period *2) Average Current : value over 1 sec period. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 23 Table 4-12: Signal Capacitance Item Pull up Resistance Symbol RCMD RDAT Total bus capacitance for each signal line Min. Max. Unit Note 10 100 k ─ 40 pF 1 cardCHOST+CBUS≦30pF ─ 10 pF 10 90 k ─ 5 pF CL Card capacitance for signal pin CCARD Pull up Resistance inside card ( pin1 ) RDAT3 Capacity Connected to Power line CC Note: WP pull-up (Rwp) Value is depend on the Host Interface drive circuit. 4.6.3 AC Characteristics (Default Speed) Figure 4-8: AC Timing Diagram (Default Speed Mode) Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 24 Table 4-13: AC Characteristics (Default Speed) Item Symbol Min. Max. Unit Note Clock Frequency (In any Sates) fsty 0 25 MHz Clock Frequency (Data transfer Mode) fPP 0 25 MHz Clock Frequency (Card identification Mode) fOD 0/100 400 *1) kHz Clock Low Time tWL 10 Clock High Time tWH Clock Rise Time tTLH Clock Fall Time ─ ns 10 ─ ns ─ 10 ns tTHL ─ 10 ns Input set-up Time tISU 5 ─ ns Input Hold Time tIH 5 ─ ns 0 14 ns Output Delay time during DataTransfer tODLY Mode CCARD ≦ 10pF ( 1Card ) CL ≦ 40pF ( 1Card ) Output Delay time during Identification tODLY 0 50 ns Mode *1) 0Hz means to stop the clock. The given minimum frequency range is for cases were continues clock is required. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 25 4.6.1 AC Characteristics (High Speed) Figure 4-9: AC Timing Diagram (High Speed Mode) Table 4-14: AC Characteristics (High Speed) Item Symbol Min. Max. Unit Note Clock Frequency (During Data transfer) fPP 0 50 Clock Low Time tWL 7 － ns Ccard≤10pF(1card) Clock High Time tWH 7 － ns Ccard≤10pF(1card) Clock Rise Time tTLH － 3 ns Ccard≤10pF(1card) Clock Fall Time tTHL － 3 ns Ccard≤10pF(1card) Input Setup Time tISU 6 － ns Ccard≤10pF(1card) Input Hold Time tIH 2 － ns Ccard≤10pF(1card) Output Delay Time TODLY － 14 ns Ccard≤40pF(1card) Output Hold Time TOH 2.5 - ns Ccard≤15pF(1card) Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 MHz Ccard≤10pF(1card) Industrial SDHC microSD Cards Page 26 Item Symbol Min. Max. Unit Note Total System capacitance for each line CL - 40 pF Ccard≤15pF(1card) 4.6.2 AC Characteristics (SDR104, SDR50, SDR25, SDR12) Figure 4-10: AC Timing Diagram (SDR104, SDR50, SDR25, SDR12 modes input) Table 4-15: Clock Signal Timing of SDR104, SDR50, SDR25, SDR12 modes input Symbol Min. Max. Unit Remark tCLK 4.80 - tCR, tCF - 0.2* tCLK ns Clock Duty 30 70 % ns 208MHz (Max.), Between rising edge, VCT= 0.975V tCR, tCF < 0.96ns (max.) at 208MHz, CCARD=10pF tCR, tCF, < 2.00ns (max.) at 100MHz, CCARD=10pF Figure 4-11: AC Timing Diagram (SDR104, SDR50, SDR25, SDR12 input timing) Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 27 Table 4-16: Clock input Timing of SDR104, SDR50, SDR25, SDR12 input timing Symbol Min. Max. Unit SDR104 mode tIS 1.40 - ns CCARD =10pF, VCT= 0.975V tIH 0.80 - ns CCARD =5pF, VCT= 0.975V Symbol Min. Max. Unit tIS 3.00 - ns CCARD =10pF, VCT= 0.975V tIH 0.80 - ns CCARD =5pF, VCT= 0.975V SDR12, SDR25 and SDR50 mode Figure 4-12: Output Timing of Fixed Window Table 4-17: Output Timing of Fixed Data Window ( SDR50, SDR25, SDR12 ) Symbol Min. Max. Unit Remark tODLY 7.5 ns tCLK>=10.0ns, CL=30pF, using driver Type B, for SDR50 tODLY 14 ns tCLK>=20.0ns, CL=40pF, using driver Type B, for SDR25 and SDR12 - ns Hold time at the tODLY (min.), CL=15pF tOH 1.5 Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 28 Figure 4-13: Output Timing of Variable Window Table 4-18: Output Timing of Variable Data Window ( SDR104 ) Symbol Min. tOP 0 ΔtOP Max. Unit Remark 2 -350 +1550 UI Card Output Phase ps Delay variation due to temperature change after tuning tODW 0.60 UI tODW=2.88ns at 208MHz Card ΔtOP is the total allowable shift of output valid window (tODW) from last system Tuning procedure. Card ΔtOP =1550pS for junction temperature of ΔT= 90°C during operation. Card ΔtOP =-350pS for junction temperature of ΔT= -20°C during operation. 6.4.5.2 Bus Timing Specification (DDR50) Figure 4-14: Clock Signal Timing Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 29 Table 4-19: Clock Signal Timing of DDR50 Symbol Min. Max. tCLK 20 - tCR, tCF - Clock Duty 45 Unit Remark ns 50MHz (Max.), Between rising edge 0.2* tCLK ns tCR, tCF, < 4.00ns (max.) at 50MHz, CCARD=10pF 55 % CMD signal timings are not shown in the figure below but For CMD signal timing refers to Figure 4-13 (Card Input Timing) and Figure 4-14 (Output Timing of Fixed Data Window) for Timing Diagram of SDR mode). Figure 4-15: Timing Diagram DAT Inputs/Outputs Referenced to CLK in DDR50 Mode Table 4-20: BUS Timings – Parameters Values (DDR50 mode) Parameter Symbol Min Max Unit Remark Input CMD (referenced to CLK rising edge) Input set-up time (*) tISU 6 - ns CCARD ≤ 10 pF (1 card) Input hold time tIH 0.8 - ns CCARD ≤ 10 pF (1 card) Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 30 Parameter Symbol Min Max Unit Remark Output CMD (referenced to CLK rising edge) Output Delay time during Data Transfer Mode tODLY - 13.7 ns CL ≤ 30 pF (1 card) Output hold time tOH 1.5 ns CL ≥ 15pF (1 card) Inputs DAT (referenced to CLK rising and falling edges) Input set-up time tISU2x 3 - ns CCARD ≤ 10 pF (1 card) Input hold time tIH2x 0.8 ns CCARD ≤ 10 pF (1 card) Outputs DAT (referenced to CLK rising and falling edges) Output Delay time during Data Transfer Mode tODLY2x 7.0 ns CL ≤ 25 pF (1 card) Output hold time tODLY2x 1.5 ns CL ≥ 15pF (1 card) (*) Input set-up time : tISU(min) is 6ns in PHYSICAL LAYER SPECIFICATION Ver.3.01 5 Card Internal Information 5.1 Security Information MKB (Media Key Block) and Media ID are Standard Information. This information is in compliance with the CPRM. Note: The security information is NOT Development information for evaluation. The Host System shall be compliance with the CPRM to use the security function. This information is kept as confidential because of security reasons. 5.2 microSD Card Registers The device has six Registers and two Status information: OCR, CID, CSD, RCA, DSR, SCR and SD Card Status, SD Status as same as SD card. DSR IS NOT SUPPORTED in this card. There are two types of register groups.   MMC compatible registers: OCR, CID, CSD, RCA, DSR, and SCR SD card Specific: SD Status Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 31 Table 5-1: microSD Card Registers Register Bit Description Name Width CID 128 Card Identification number RCA 16 Relative Card Address DSR 16 Optional : Driver Stage CSD 128 Card Specific Data SCR 64 SD Configuration OCR 32 Operation conditions CSR 32 Card Status CMD6 512 Switch Function Status SD Status 512 Status bits and card features 5.2.1 OCR Register This 32-bit register describes operating voltage range and status bit in the power supply. Table 5-2: OCR Register Definition OCR bit position Response Value OCR Fields Definition 0-3 32GB reserved 0 0 0 4-6 reserved 0 0 0 7 Reserved for Low Voltage Range 0 0 0 8-14 reserved 0 0 0 2.7 - 2.8 1 1 1 2.8 - 2.9 1 1 1 2.9 - 3.0 1 1 1 18 3.0 - 3.1 1 1 1 19 3.1 - 3.2 1 1 1 20 3.2 - 3.3 1 1 1 21 3.3 - 3.4 1 1 1 22 3.4 - 3.5 1 1 1 3.5 - 3.6 15 16 17 VDD voltage Window 1 1 1 24(1) 23 Switching to 1.8V Accepted (S18A) 1 1 1 25-29 reserved 0 0 0 30 Card Capacity Status (CCS)(2) 0=SD Memory Card, 1= (SDHC or SDXC) 31 Card power up status bit (busy)(3) “ 0 “ = busy “ 1 “ = ready Notes: 1. bit24: Only UHS-I card supports this bit. 2. bit30 : This bit is valid only when the card power up status bit is set. 3. bit31: This bit is set to LOW if the card has not finished the power up routine. bit 23-4: Describes the microSD Card Voltage bit 31 indicates the card power up status. Value “1” is set after power up and initialization procedure completed. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 32 5.2.2 CID Register The CID (Card Identification) register is 128-bit width. It contains the card identification information. The Value of CID Register is vender specific. Table 5-3: CID register Initial Value CIDslice Field Width 8GB 16GB Comment 32GB MID 8 [127:120] 0x02 Manufacture ID(0x02 = Toshiba) OID 16 [119:104] 0x544D OEM/Application ID (0x544D("TM") = Toshiba) 32GB:"UC0D5" PNM 40 [103:64] tbd 0x5543304435 for 32GB tbd 64GB:"UC0E5" 128GB:"UC0F5" PRV 8 [63:56] 0x52 Product Revision PSN 32 [55:24] 0xnnnnnnnn Product serial number - 4 [23:20] 0x0 reserved MDT 12 [19:8] 0xmmm Manufacturing data CRC 7 [7:1] CRC CRC 7 Checksum (chapter 7, SD Physical spec 1 [0:0] 0x1 Notes: 1. The manufacturing date composed of two-hexadecimal digits. CID-Slice [11:8] Month Field (Exp. 1h = January) CID-Slice [19:12] Year Field (Exp. 0h = 2000) 1 not used, always 1 5.2.3 CSD Register CSD is Card-Specific Data register provides information on 128bit width. Some field of this register can writable by PROGRAM_CSD (CMD27). Table 5-4: CSD register Cell Initial Value Type CSDslice 2 R [127:126] 01b - 6 R [125:120] 00_0000b TAAC 8 R [119:112] 0000_1110b 1ms(time unit) * 1.0(time value) = 1ms 8 R [111:104] 0000_0000b 0 clock Cycle Field Width CSD＿STRUCTURE NSAC 8GB 16GB 32GB Comment CSD version 2.0(High Capacity and Extended Capacity) reserved SDR104 0010_1011b 200Mbit/s SDR50 0000_1011b 100Mbit/s DDR50 0000_1011b 100Mbit/s TRAN_SPEED SDR25 [103:96] 0101_1010b 50Mbit/s SDR12 8 0011_0010b 25Mbit/s HS 0101_1010b 50Mbit/s DS 0011_0010b 25Mbit/s Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 R Industrial SDHC microSD Cards Page 33 Cell Initial Value Type CSDslice 12 R [95:84] 0101_1011_0101b READ_BL_LEN 4 R [83:80] 1001b READ_BL_PARTIAL 1 R [79:79] 0 “ 0 “: Partial block read is inhibited and only unit of block access is allowed. WRITE_BLK_MISALIG N 1 R [78:78] 0 “ 0 “ : Not allowed on this card READ_BLK_MISALIGN 1 R [77:77] 0 “ 0 “ : Invalid on this card DSR_IMP 1 R [76:76] 0 “ 0 “ :DSR NOT implemented - 6 R [75:70] 00_0000b Field Width CCC 8GB tbd 16GB 32GB Comment Class 0,2,4,5,7,8,10 are supported 512Bytes reserved EE87h For memory capacity = (C_SIZE+1) * 512K byte 32GB C_SIZE 22 R [69:48] tbd - 1 R [47:47] 0 reserved ERASE_BLK_EN 1 R [46:46] 1 “ 1 “ :Can erase by WRITE_BL_LEN unit (512 Bytes) SECTOR_SIZE 7 R [45:39] 111_1111b This size of an erasable sector. This field is fixed to 7F-h. Sector size = 64KBytes. WP_GRP_SIZE 7 R [38:32] 000_0000b This size of a write protected group. This field is fixed to 00-h. 1 Write Protect Group = 1sector. WP_GRP_ENABLE 1 R [31:31] 0 value of 0 means no group write protection possible. - 2 R [30:29] 00b reserved R2W_FACTOR 3 R [28:26] 010b This field is fixed to “2-h”, which indicates 4 multiples. However, host should not use this factor and should use 250ms for write timeout. WRITE_BL_LEN 4 R [25:22] 1001b “ 9 “: 512Bytes on this card. WRITE_BL_PARTIAL 1 R [21:21] 0 - 5 R [20:16] 0_0000b FILE_FORMAT_GRP 1 R [15:15] 0 This field is set to “0”. Host should not use this field. COPY 1 R/W [14:14] 0 “ 0 “ : Original on this card PERM_WRITE_PROTE CT 1 R/W [13:13] 0 “ 0 “: Not protected / Writable on this card TMP_WRITE_PROTEC T 1 R/W [12:12] 0 FILE_FORMAT 2 R [11:10] 00b “ 0 “: Hard disk-like file system with partition table on this card. - 2 R [9:8] 00b reserved Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 “ 0 “: Only the WRITE_BL_LEN size or 512Bytes are available reserved “ 0 “: Not protected / Writable on this card Industrial SDHC microSD Cards Page 34 Cell Initial Value Type CSDslice 7 R/W [7:1] CRC CRC 7 Checksum 1 - [0:0] 1 not used, always 1 Field Width CRC - 8GB 16GB 32GB Comment Notes: 1.Cell Types: R: Read Only, R/W: Writable and Readable, R/W(1): One-time Writable / Readable 2. Erase of one data block is not allowed in this card. This information is indicated by “ERASE_BLK_EN”. Host System should refer this value before one data block size erase. 5.2.4 RCA Register The writable 16bit relative card address register carries the card address in SD Card mode. 5.2.5 DSR Register This register is not used 5.2.6 SCR Register CR(SD Card Configuration Register) provides information on SD Memory Cardʼs special features. The size of SCR Register is 64 bit and al bits are read only Table 5-5: The SCR Fields Initial Value SCRComment slice 32GB 64GB 128GB Field Width SCR_STRUCTURE 4 [63:60] 0x0 SCR version 1.0(Version 1.01-3.00) SD_SPEC 4 [59:56] 0x2 “ 2 “ : Version 2.00 or Version 3.0X, Version 4.xx ( Refer to SD_SPEC3 and SD_SPEC4 ) DATA_STAT_AFTER_ERASE 1 [55:55] 0x1 “ 1 “ : on this card SD_SECURITY 3 [54:52] tbd 0x3 for 32GB SD_BUS_WIDTHS 4 [51:48] 0x5 “ 0101 “ : 1 and 4 bit supported SD_SPEC3 1 [47:47] 0x1 “ 1 “ : Version 3.0X, Version 4.xx ( Refer to SD_SPEC4 ) EX_SECURITY 4 [46:43] 0x0 Extended Security is not supported. SD_SPEC4 1 [42:42] 0x1 “ 1 “ : Version 4.xx - 6 [41:36] 0x0 reserved CMD_SUPPORT 4 [35:32] 0x3 “ 11 “ : CMD23 and CMD20 support 32 [31:0] 0x3202nnnn Note: All bits are read only “3“ : Security Version 2.00 ”4”：Security Version 3.00 reserved for manufacture usage 5.2.7 Card Status This field is intended to transmit the cardʼs status information to the host. Table 5-6: Card Status Identifier Bits Type Value Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 35 Identifier Bits Type Value OUT_OF_RANGE 31 ER “ 0 “ = no error , “ 1 “ = error X ADDRESS_ERROR 30 ER “ 0 “ = no error , “ 1 “ = error X BLOCK_LEN_ERROR 29 ER “ 0 “ = no error , “ 1 “ = error X ERASE_SEQ_ERROR 28 E R “ 0 “ = no error , “ 1 “ = error ERASE_PARAM 27 ER “ 0 “ = no error , “ 1 “ = error X WP_VIOLATION 26 ER “ 0 “ = not protected , “ 1 “ = protected X CARD_IS_LOCKED 25 S X “ 0 “ = card unlocked , “ 1 “ = card locked LOCK_UNLOCK_FAILED 24 ER “ 0 “ = no error , “ 1 “ = error X COM_CRC_ERROR 23 E R “ 0 “ = no error , “ 1 “ = error ILLEGAL_COMMAND 22 E R “ 0 “ = no error , “ 1 “ = error CARD_ECC_FAILED 21 ER “ 0 “ = success , “ 1 “ = failure X CC_ERROR 20 ER “ 0 “ = no error , “ 1 “ = error X ERROE 19 ER “ 0 “ = no error , “ 1 “ = error X - 18 - 17 reserved reserved for DEFERRED_RESPONSE CSD_OVERWRITE 16 ER “ 0 “ = no error , “ 1 “ = error X WE_ERASE_SKIP 15 ER “ 0 “ = not protected , “ 1 “ = protected X CARD_ECC_DISABLED 14 S X “ 0 “ = enabled , “ 1 “ = disabled 13 S R “ 0 “ = cleared , “ 1 “ = set ERASE_STATE CURRENT_STATE 12 – S X “ 0 “ = idle , “ 1 “ = ready , “ 2 “ = ident , “ 3 “ = stanby “ 4 “ = tran , “ 5 “ = data , 9 “ 6 “ = rcv , “ 7 “ = prg “ 8 “ = dis , “ 9 – 14 “ = reserved “ 15 “ = reserved for I/O mode READY_FOR_DATA - 8 7,6 APP_CMD 5 - 4 AKE_SEQ_ERROR 3 - 2 S X “ 0 “ = not ready , “ 1 “ = ready S R “ 0 “ = Disabled , “ 1 “ = Enabled reserved for SD I/O Card E R “ 0 “ = no error , “ 1 “ = error reserved 1,0 reserved Notes: E: Error bit , S: Status bit , R: Detected and set for actual command response. X: Detected and set during command execution. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 36 5.2.8 SD Status Table 5-7: SD Status Field DAT_BUS_WIDTH SD Width Type Status slice 2 Initial Value Comment 8GB 16GB 32GB 00b 1bit: HS1bit, SD1bit, HSSPI, SPI 10b 4bit: SDR104, DDR50, SDR50, SDR25, SDR12, HS4bit, SD4bit SR [511:510] SECUERED_MODE 1 SR [509] 1 reserved 8 [508:502] 0x00 reserved reserved 6 [501:496] 0x00 reserved SD_CARD_TYPE 16 SR [495:480] 0x0000 tbd Secured Mode Regular SD RD/WR card 0x05000000 for 32GB:81,920KB 32GB SIZE_OF_PROTECTED_AREA 32 SR [479:448] SPEED_CLASS 8 SR [447:440] PERFORMANCE_MOVE 8 SR [439:432] AU_SIZE 4 SR [431:428] 0x9 0x9:4MB reserved 4 [427:424] 0x0 reserved ERASE_SIZE 16 SR [423:408] 0x0020 32AU ERASE_TIMEOUT 6 SR [407:402] 0x01 1sec ERASE_OFFSET 2 SR [401:400] 11b 3sec UHS_SPEED_GRADE 4 SR [399:396] 0x3 0x3:30MB/sec and above UHS_AU_SIZE 4 SR [395:392] 0xC 0xC:16MB - 80 [391:312] ALL 0 reserved - 312 [311:0] ALL 0 reserved for manufacture 0x04 tbd Class10 0x02 for 32GB 0x02:2MB/s、 0x00:0MB/s S : Status bit , R : Set based on Command Response Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 37 5.2.9 Switch Function Status Switch function command (CMD6) is used to switch or expand memory card functions. Currently four function groups are defined: (1) Access Mode: Selection of SD bus interface speed modes. (2) Command System: A specific function can be extended and controlled by a set of shared commands. (3) Driver Strength Selection of suitable output driver strength in UHS-I modes depends on host environment. (4) Power Limit Selection to limit the maximum power depends on host power supply capability and heat release capability. Table 5-8: Switch Function Status Description Width Bits Bus Speed Mode 0x0 0x1 SDR104/ SDR50/ DDR50 16 [511:496] 8GB 16GB 0x4 SDR25 0x0〜0x4 SDR12 0x0〜0x4 HS 0x0 DS 0x0 tbd 0x00C8 (0.72W/200mA) tbd tbd 0x00FA (0.90W/250mA) tbd tbd tbd tbd 0x00FA (0.90W/250mA) tbd tbd 0x00FA (0.90W/250mA) tbd tbd 0x00C8 (0.72W/200mA) tbd tbd 0x0064 (0.36W/100mA) tbd tbd 0x00C8 (0.72W/200mA) tbd tbd 0x0064 (0.36W/100mA) 0x00FA (0.90W/250mA) Function Gr 6, information. 16 [495:480] - - 0x8001 Function Gr 5, information. 16 [479:464] - - 0x8001 Function Gr4, information. 16 SDR104[463:448] 12 DDR50 HS,DS - 0x801F - 0x8001 Function Gr3, information. 16 - 0x800F - 0x8001 Function Gr 2, information. 16 [431:416] - - 0x8001 Function Gr1, 16 [415:400] SDR10412 DDR50 - 0x801F SDR104[447:432] 12 DDR50 HS,DS Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 32GB tbd 0x2 0x3 Maximum Current Consumption Value Set Value of Gr4 Industrial SDHC microSD Cards Page 38 Description Width Bits Bus Speed Mode Set Value of Gr4 Value 8GB 16GB 32GB information. HS,DS - 0x8003 Function Gr6, information. 4 [399:396] - - Set Response Value Function Gr5, information. 4 [395:392] - - Set Response Value Function Gr4, information. 4 [391:388] - - Set Response Value Function Gr3, information. 4 [387:384] - - Set Response Value Function Gr2, information. 4 [383:380] - - Set Response Value Function Gr1, information. 4 [379:376] - - Set Response Value Data Structure Version 8 [375:368] - - 0x00 Busy Status of functions in Gr6 16 [367:352] - - 0x0000 Busy Status of functions in Gr5 16 [351:336] - - 0x0000 Busy Status of functions in Gr4 16 [335:320] - - 0x0000 Busy Status of functions in Gr3 16 [319:304] - - 0x0000 Busy Status of functions in Gr2 16 [303:288] - - 0x0000 Busy Status of functions in Gr1 16 [287:272] - - 0x0000 Reserved 272 [271:0] - - ALL 0 5.3 Logical Format The microSD card is formatted before shipping to be compliant to the SD Card FILE SYSTEM SPECIFICATION. The following parameters may be changed if the host system is not compliant with the SD Card Format Specification. The data of the logical format is described in section 5.3.3 (8GB Card), section 5.3.4 (16GB Card) and section 5.3.5 (32GB Card). Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 39 5.3.1 microSD Card Capacities Table 5-9: microSD Card Capacities Card Capacities Item 8GB Sector 16GB KB Sector 32GB KB Whole Capacity TBD TBD TBD TBD User Data Area Size TBD TBD TBD TBD Protected Area Size TBD TBD TBD TBD Sector KB 62,660,608 31,330,304 62,529,536 31,264,768 131,072 65,536 5.3.2 microSD card System Information Table 5-10: microSD Card System information Item User Data Area Protected Area Data Boundary unit size (KB) Cluster Size (KB) Data Boundary unit size (KB) Cluster Size (KB) Card Capacities 8GB TBD 16GB TBD TBD TBD TBD TBD TBD TBD 32GB 4,096 32 16 16 5.3.3 Data of the logical format of a 8GB Card (Contact Viking) 5.3.4 Data of the logical format of a 16GB Card (Contact Viking) 5.3.5 Data of the logical format of a 32GB Card (Contact Viking) 6 SD Specification Compliance 1) Non Supported Registers: DSR Register (Optional register: PHISYCAL LAYER SPECIFICATION 5.5) Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 40 2) Non Supported Functions: Programmable Card Output Driver (Optional in PHYSICAL LAYER SPECIFICATION 6.5) Card ʻs Internal Write Protect (Optional in PHYSICAL LAYER SPECIFICATION 4.3.6.) 3) Non Specified Command: CMD4 SET_DSR CMD28 SET_WRITE_PROT CMD29 CLR_WRITE_PROT CMD30 SEND_WRITE_PROT CMD56 GEN_CMD 7 Reliability Guidance This reliability guidance is intended to provide some guidance related to using raw NAND flash. Although random bit errors may occur during use, it does not necessarily mean that a block is bad. Generally, a block should be marked as bad when a program status failure or erase status failure is detected. The other failure modes may be recovered by a block erase. ECC treatment for read data is mandatory due to the following Data Retention and Read Disturb failures. Write/Erase Endurance Write/Erase endurance failures may occur in a cell, page, or block, and are detected by doing a status read after either an auto program or auto block erase operation. The cumulative bad block count will increase along with the number of write/erase cycles. Data Retention The data in memory may change after a certain amount of storage time. This is due to an electrical charge loss or charge gain. After block erasure and reprogramming, the block may become usable again. Also write/erase endurance deteriorates data retention capability. The figure below shows a generic trend of relationship between write/erase endurance and data retention. Data Retention Read Disturb A read operation may disturb the data in memory. The data may change due to charge gain. Usually, bit errors occur on other pages in the block, not the page being read. After a large number of read cycles (between block erases), a tiny charge may build up and can cause a cell to be soft programmed to another state. After block erasure and reprogramming, the block may become usable again. Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 41 Considering the above failure modes, Viking recommends following usage model: Avoid any excessive iteration of resets and initialization sequences (card identification mode) as far much as possible after power-on, which may result in read disturb failure. The resets include hardware resets and software resets. i.e. 1) The iteration of the following command sequence: CMD0 -ACMD41 (The assertion of ACMD41 implies a count of internal read operation in Raw NAND.   CMD0: Go idle state command, ACMD41 : SD send operation command 2) Iteration of the following command: ACMD43  ACMD43 : Get MKB command Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 42 8 microSD Card Mechanical Dimensions Note: 1. All dimensions in mm 2. Tolerance is ± 0.15 mm Datasheet: PSUSDxxxxCxxxxxN Revision A | April 17, 2017 Industrial SDHC microSD Cards Page 43