B92.935KGU.00104

RoHS Compliant PCI Express Flash Drive PV210-M280 Product Specifications June 23, 2021 Version 1.0 Apacer Technology Inc. 1F, No.32, Zhongcheng Rd., Tucheng Dist., New Taipei City, Taiwan, R.O.C Tel: +886-2-2267-8000 www.apacer.com Fax: +886-2-2267-2261 Specifications Overview:    Temperature Range – Compliant with PCIe Express 3.1 – Compliant with NVMe 1.3 Standard: 0°C to 70°C – Compatible with PCIe Gen3 x4 interface Wide: -40°C to 85°C – – Capacity –   PCIe Interface  240, 480, 960, 1,920 GB – Interface burst read/write: 4 GB/sec – Sequential read: up to 3,130 MB/sec – Sequential write: up to 2,620 MB/sec – Random read (4K): up to 565,000 IOPS – Random write (4K): up to 521,000 IOPS   3.3 V ± 5% Power Consumption* – Active mode: 1,850 mA – Idle mode: 255 mA Connector Type –  Flash Management Storage: -40°C to 100°C Supply Voltage – Performance* Operating: 75-pin M.2 module pinout Power Management – Low-Density Parity-Check (LDPC) Code – Supports APST – Global Wear Leveling – Supports ASPM L1.2 – Flash bad-block management – Flash Translation Layer: Page Mapping – S.M.A.R.T. – Power Failure Management – TRIM – Hyper Cache Technology – Thermal Sensor – Over-Provisioning – Thermal Throttling – End-to-End Data Protection – CoreGlacierTM***   TM – DataRAID – NVMe Secure Erase  DRAM Cache for Enhanced Random Performance  NAND Flash Type: 3D TLC (BiCS3)  MTBF: >3,000,000 hours  Endurance (in drive writes per day : DWPD) – 240 GB: 3.17 DWPD – 480 GB: 2.77 DWPD – 960 GB: 2.92 DWPD – 1,920 GB: 3.62 DWPD  Security – AES 256-bit hardware encryption – Trusted Computing Group (TCG) Opal 2.0 (optional) Reliability Form Factor – Form Factor: M.2 2280-D5-M Key – Dimensions (unit: mm): Double side: 22.00 x 80.00 x 3.88 CoreGlacierTM: 22.00 x 80.00 x 4.08(max) – Net Weight: 8.96g ± 5%  LED Indicators for Drive Behavior  RoHS Compliant *Varies from capacities. The values for performances and power consumptions presented are typical and may vary depending on flash configurations or platform settings. **Windows 10 (version 1703) onwards supports the HMB (Host Memory Buffer) function. ***Only supported on wide temperature series 1 © 2021 Apacer Technology Inc. Table of Contents 1. General Descriptions ........................................................................4 2. Functional Block ...............................................................................4 3. Pin Assignments ................................................................................5 4. Product Specifications ......................................................................7 4.1 Capacity ......................................................................................................................................... 7 4.2 Performance .................................................................................................................................. 7 4.3 Environmental Specifications ........................................................................................................ 7 4.4 Mean Time Between Failures (MTBF) .......................................................................................... 8 4.5 Certification and Compliance......................................................................................................... 8 4.6 Endurance ..................................................................................................................................... 8 4.7 LED Indicator Behavior .................................................................................................................. 9 5. Flash Management ..........................................................................10 5.1 Error Correction/Detection ........................................................................................................... 10 5.2 Bad Block Management .............................................................................................................. 10 5.3 Global Wear Leveling .................................................................................................................. 10 5.4 Power Failure Management ........................................................................................................ 10 5.5 TRIM ............................................................................................................................................ 11 5.6 Flash Translation Layer – Page Mapping.................................................................................... 11 5.7 Hyper Cache Technology ............................................................................................................ 11 5.8 Over-Provisioning ........................................................................................................................ 11 5.9 DataRAIDTM ................................................................................................................................. 11 5.10 NVMe Secure Erase .................................................................................................................. 11 6. Security & Reliability Features ......................................................12 6.1 Advanced Encryption Standard ................................................................................................... 12 6.2 TCG Opal (optional) .................................................................................................................... 12 6.3 Thermal Sensor ........................................................................................................................... 12 6.4 Thermal Throttling ....................................................................................................................... 12 6.5 End-to-End Data Protection......................................................................................................... 13 6.6 CoreGlacierTM .............................................................................................................................. 13 7. Software Interface ..........................................................................14 7.1 Command Set .............................................................................................................................. 14 2 © 2021 Apacer Technology Inc. 7.2 S.M.A.R.T. ................................................................................................................................... 15 8. Electrical Specifications.................................................................17 8.1 Operating Voltage ........................................................................................................................ 17 8.2 Power Consumption .................................................................................................................... 17 9. Physical Characteristics .................................................................18 9.1 Double Side ................................................................................................................................. 18 9.2 CoreGlacier ................................................................................................................................. 18 9.3 Net Weight ................................................................................................................................... 19 10. Product Ordering Information .......................................................20 10.1 Product Code Designations ....................................................................................................... 20 10.2 Valid Combinations .................................................................................................................... 21 3 © 2021 Apacer Technology Inc. 1. General Descriptions Apacer PV210-M280 is the fastest SSD designed as M.2 2280 mechanical dimensions, providing full compliance with PCIe Gen3 x4 interface and NVMe 1.3 specifications. Built with a powerful PCIe controller, PV210-M280 delivers outstanding performance in data transfer, reaching up to 565,000/521,000 and 3,130/2,620 MB/s in IOPS and sequential read/write. The extreme thin and light form factor makes PV210-M280 the ideal choice for mobile computing systems, which appears to be the trend in near future. In terms of security, Advanced Encryption Standard (AES) and Trusted Computing Group (TCG) Opal (optional) ensure data security and provide users with a peace of mind knowing their data is safeguarded against unauthorized use at all times. Furthermore, with End-to-End Data Protection, data integrity can be assured at multiple points in the path to enable reliable delivery of data transfers. Regarding reliability, PV210-M280 is built with a powerful PCIe controller that supports on-the-module ECC as well as efficient wear leveling scheme. In terms of power efficiency, PV210-M280 is compliant with PCIe Gen3 x4 interface standard so that it can operate on power management modes, which greatly save on power consumption. 2. Functional Block DDR4 DRAM M Figure 2-1 Functional Block Diagram 4 © 2021 Apacer Technology Inc. 3. Pin Assignments This connector does not support hot plug capability. There are a total of 75 pins. 12 pin locations are used for mechanical key locations; this allows such a module to plug into Key M connectors. Table 3-1 Pin Assignments Pin 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 Type GND 3.3V GND 3.3V PETn3 N/C PETp3 N/C GND LED1#(O) PERn3 3.3V PERp3 3.3V GND 3.3V PETn2 3.3V PETp2 N/C GND N/C PERn2 N/C PERp2 N/C GND N/C PETn1 N/C PETp1 N/C Description Ground 3.3V source Ground 3.3V source PCIe TX Differential signal defined by the PCI Express M.2 spec No connect* PCIe TX Differential signal defined by the PCI Express M.2 spec No connect* Ground Status indicators via LED devices PCIe RX Differential signal defined by the PCI Express M.2 spec 3.3V source PCIe RX Differential signals defined by the PCI Express M.2 spec 3.3V source Ground 3.3V source PCIe TX Differential signal defined by the PCI Express M.2 spec 3.3V source PCIe TX Differential signal defined by the PCI Express M.2 spec No connect* Ground No connect* PCIe RX Differential signal defined by the PCI Express M.2 spec No connect* PCIe RX Differential signal defined by the PCI Express M.2 spec No connect* Ground No connect* PCIe TX Differential signal defined by the PCI Express M.2 spec No connect* PCIe TX Differential signal defined by the PCI Express M.2 spec No connect* 5 © 2021 Apacer Technology Inc. Table 3-1 Pin Assignments Pin 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 Type GND N/C PERn1 N/C PERp1 N/C GND SMB_CLK PETn0 SMB_DATA PETp0 ALERT# GND I2C_CLK PERn0 I2C_DATA PERp0 PERST#(I)(0/3.3V) GND CLKREQ#(I/O)(0/3.3V) REFCLKn PEWAKE#(I/O)(0/3.3V) REFCLKp Reserved for MFG DATA GND Reserved for MFG CLOCK Module Key Module Key Module Key Module Key Module Key Module Key Module Key Module Key N/C SUSCLK(32KHz) (I)(0/3.3V) PEDET (NC-PCIe) 3.3V GND 3.3V GND 3.3V GND Description Ground No connect* PCIe RX Differential signal defined by the PCI Express M.2 spec No connect* PCIe RX Differential signal defined by the PCI Express M.2 spec No connect* Ground SMBus clock; Open Drain with pull up on platform PCIe TX Differential signal defined by the PCI Express M.2 spec SMBus Data; Open Drain with pull up on platform PCIe TX Differential signal defined by the PCI Express M.2 spec Alert notification to host system. Open Drain with pull up on platform, Active low Signals Ground I2C clock; Open Drain with pull up on platform PCIe RX Differential signal defined by the PCI Express M.2 spec I2C Data; Open Drain with pull up on platform PCIe RX Differential signal defined by the PCI Express M.2 spec PE-Reset is a functional reset to the card as specification. defined by the PCIe Mini CEM Ground Clock Request is a reference clock request signal as defined by the PCIe Mini CEM specification; Also used by L1 PM Substates. PCIe Reference Clock signals (100 MHz) spec. defined by the PCI Express M.2 Open Drain with pull up on platform; Active Low. PCIe PME Wake. PCIe Reference Clock signals (100 MHz) spec. defined by the PCI Express M.2 Manufacturing Data line. Used for SSD manufacturing only. Not used in normal operation. Pins should be left N/C in platform Socket. Ground Manufacturing Clock line. Used for SSD manufacturing only. Not used in normal operation. Pins should be left N/C in platform Socket. Module Key Module Key Module Key Module Key Module Key Module Key Module Key Module Key No connect* 32.768 kHz clock supply input that is provided by the platform chipset to reduce power and cost for the module. Host I/F Indication; No connect for PCIe. 3.3V source Ground 3.3V source Ground 3.3V source Ground *Reserved by Apacer, please do not connect on a host. 6 © 2021 Apacer Technology Inc. 4. Product Specifications 4.1 Capacity Capacity specifications of PV210-M280 are available as shown in Table 4-1. It lists the specific capacity and the default numbers of heads, sectors and cylinders for each product line. Table 4-1 Capacity Specifications Capacity Total bytes* Total LBA 240 GB 240,057,409,536 468,862,128 480 GB 480,103,981,056 937,703,088 960 GB 960,197,124,096 1,875,385,008 1,920 GB 1,920,383,410,176 3,750,748,848 *Display of total bytes varies from file systems, which means not all of the bytes can be used for storage. **Notes: 1 GB = 1,000,000,000 bytes; 1 sector = 512 bytes. LBA count addressed in the table above indicates total user storage capacity and will remain the same throughout the lifespan of the device. However, the total usable capacity of the SSD is most likely to be less than the total physical capacity because a small portion of the capacity is reserved for device maintenance usages. 4.2 Performance Performance of PV210-M280 is listed below in Table 4-2. Table 4-2 Performance Specifications Capacity 240 GB 480 GB 960 GB 1,920 GB Sequential Read* (MB/s) 2,735 3,070 3,105 3,130 Sequential Write* (MB/s) 1,040 2,085 2,620 2,565 Random Read IOPS** (4K) 152,000 300,000 565,000 495,000 Random Write IOPS** (4K) 238,000 461,000 521,000 517,000 Performance Note: Results may differ from various flash configurations or host system setting. *Sequential performance is based on CrystalDiskMark 5.2.1 with file size 1,000MB. **Random performance measured using IOMeter with Queue Depth 64. 4.3 Environmental Specifications Environmental specifications of PV210-M280 are shown in Table 4-3. Table 4-3 Environmental Specifications Item Specifications Operating temp. 0°C to 70°C (Standard); -40°C to 85°C (Wide) Non-operating temp. -40°C to 100°C Operating vibration 7.69 GRMS, 20~2000 Hz/random (compliant with MIL-STD-810G) Non-operating vibration 4.02 GRMS, 15~2000 Hz/random (compliant with MIL-STD-810G) Operating shock 50(G)/11ms/half sine (compliant with MIL-STD-202G) Non-operating shock 1,500(G)/0.5(ms)/half sine (compliant with MIL-STD-883K) Note: Shock and Vibration specifications are subject to change without notice. 7 © 2021 Apacer Technology Inc. 4.4 Mean Time Between Failures (MTBF) Mean Time Between Failures (MTBF) is predicted based on reliability data for the individual components in PV210-M280. The prediction result for PV210-M280 is more than 3,000,000 hours. Note: The MTBF is predicated and calculated based on “Telcordia Technologies Special Report, SR332, Issue 3” method. 4.5 Certification and Compliance PV210-M280 complies with the following standards:     CE FCC RoHS MIL-STD-810G 4.6 Endurance The endurance of a storage device is predicted by Drive Writes Per Day based on several factors related to usage, such as the amount of data written into the drive, block management conditions, and daily workload for the drive. Thus, key factors, such as Write Amplifications and the number of P/E cycles, can influence the lifespan of the drive. Table 4-4 Drive Writes Per Day Capacity Drive Writes Per Day 240 GB 3.17 480 GB 2.77 960 GB 2.92 1,920 GB 3.62 Note:  This estimation complies with JEDEC JESD-219, enterprise endurance workload of random data with payload size distribution.  Flash vendor guaranteed 3D NAND TLC P/E cycle: 3K  WAF may vary from capacity, flash configurations and writing behavior on each platform.  1 Terabyte = 1,024GB  DWPD (Drive Writes Per Day) is calculated based on the number of times that user overwrites the entire capacity of an SSD per day of its lifetime during the warranty period. (3D NAND TLC warranty: 2 years) 8 © 2021 Apacer Technology Inc. 4.7 LED Indicator Behavior The behavior of the PV210-M280 LED indicators is described in Table 4-5. Table 4-5 LED Behavior Location LED Description LED A DAS LED blinks when the drive is being accessed 9 © 2021 Apacer Technology Inc. 5. Flash Management 5.1 Error Correction/Detection PV210-M280 implements a hardware ECC scheme, based on the Low Density Parity Check (LDPC). LDPC is a class of linear block error correcting code which has apparent coding gain over BCH code because LDPC code includes both hard decoding and soft decoding algorithms. With the error rate decreasing, LDPC can extend SSD endurance and increase data reliability while reading raw data inside a flash chip. 5.2 Bad Block Management Current production technology is unable to guarantee total reliability of NAND flash memory array. When a flash memory device leaves factory, it comes with a minimal number of initial bad blocks during production or out-of-factory as there is no currently known technology that produce flash chips free of bad blocks. In addition, bad blocks may develop during program/erase cycles. Since bad blocks are inevitable, the solution is to keep them in control. Apacer flash devices are programmed with ECC, page mapping technique and S.M.A.R.T to reduce invalidity or error. Once bad blocks are detected, data in those blocks will be transferred to free blocks and error will be corrected by designated algorithms. 5.3 Global Wear Leveling Flash memory devices differ from Hard Disk Drives (HDDs) in terms of how blocks are utilized. For HDDs, when a change is made to stored data, like erase or update, the controller mechanism on HDDs will perform overwrites on blocks. Unlike HDDs, flash blocks cannot be overwritten and each P/E cycle wears down the lifespan of blocks gradually. Repeatedly program/erase cycles performed on the same memory cells will eventually cause some blocks to age faster than others. This would bring flash storages to their end of service term sooner. Global wear leveling is an important mechanism that levels out the wearing of all blocks so that the wearing-down of all blocks can be almost evenly distributed. This will increase the lifespan of SSDs. 5.4 Power Failure Management Power Failure Management plays a crucial role when power supply becomes unstable. Power disruption may occur when users are storing data into the SSD, leading to instability in the drive. However, with Power Failure Management, a firmware protection mechanism will be activated to scan pages and blocks once power is resumed. Valid data will be transferred to new blocks for merging and the mapping table will be rebuilt. Therefore, data reliability can be reinforced, preventing damage to data stored in the NAND Flash. Note: The controller unit of this product model is designed with a DRAM as a write cache for improved performance and data efficiency. Though unlikely to happen in most cases, the data cached in the volatile DRAM might be potentially affected if a sudden power loss takes place before the cached data is flushed into non-volatile NAND flash memory. 10 © 2021 Apacer Technology Inc. 5.5 TRIM TRIM is a feature which helps improve the read/write performance and speed of solid-state drives (SSD). Unlike hard disk drives (HDD), SSDs are not able to overwrite existing data, so the available space gradually becomes smaller with each use. With the TRIM command, the operating system can inform the SSD which blocks of data are no longer in use and can be removed permanently. Thus, the SSD will perform the erase action, which prevents unused data from occupying blocks all the time. 5.6 Flash Translation Layer – Page Mapping Page mapping is an advanced flash management technology whose essence lies in the ability to gather data, distribute the data into flash pages automatically, and then schedule the data to be evenly written. Page-level mapping uses one page as the unit of mapping. The most important characteristic is that each logical page can be mapped to any physical page on the flash memory device. This mapping algorithm allows different sizes of data to be written to a block as if the data is written to a data pool and it does not need to take extra operations to process a write command. Thus, page mapping is adopted to increase random access speed and improve SSD lifespan, reduce block erase frequency, and achieve optimized performance and lifespan. 5.7 Hyper Cache Technology Apacer proprietary Hyper Cache technology uses a portion of the available capacity as SLC (1bit-percell) NAND flash memory, called Hyper cache mode. When data is written to SSD, the firmware will direct the data to Hyper Cache mode, providing excellent performance to handle various scenarios in industrial use. 5.8 Over-Provisioning Over-Provisioning (OP) is a certain portion of the SSD capacity exclusively for increasing Garbage Collection (GC) efficiency, especially when the SSD is filled to full capacity or performs a heavy mixed-random workload. OP has the advantages of providing extended life expectancy, reliable data integrity, and high sustained write performance. 5.9 DataRAIDTM Apacer’s DataRAID algorithm applies an additional level of protection and error-checking. Using this algorithm, a certain amount of space is given over to aggregating and resaving the existing parity data used for error checking. So, in the event that data becomes corrupted, the parity data can be compared to the existing uncorrupted data and the content of the corrupted data can be rebuilt. 5.10 NVMe Secure Erase NVMe Secure Erase is an NVMe drive sanitize command currently embedded in most of the storage drives. Defined in NVMe specifications, NVMe Secure Erase is part of Format NVM command that allows storage drives to erase all user data areas. The erase process usually runs on the firmware level as most of the NVMe-based storage media currently in the market are built-in with this command. NVMe Secure Erase can securely wipe out the user data in the drive and protects it from malicious attack. 11 © 2021 Apacer Technology Inc. 6. Security & Reliability Features 6.1 Advanced Encryption Standard Advanced Encryption Standard (AES) is a specification for the encryption of electronic data. AES has been adopted by the U.S. government since 2001 to protect classified information and is now widely implemented in embedded computing applications. The AES algorithm used in software and hardware is symmetric so that encrypting/decrypting requires the same encryption key. Without the key, the encrypted data is inaccessible to ensure information security. Notably in flash memory applications, AES 256-bit hardware encryption is the mainstream to protect sensitive or confidential data. The hardware encryption provides better performance, reliability, and security than software encryption. It uses a dedicated processor, which is built inside the controller, to process the encryption and decryption. This enormously shortens the processing time and makes it efficient. 6.2 TCG Opal (optional) Developed by the Trusted Computing Group (TCG), an organization whose members work together to formulate industry standards, Opal is a set of security specifications used for applying hardwarebased encryption to storage devices. Hardware encryption has many advantages. First of all, it transfers the computational load of the encryption process to dedicated processors, reducing the stress on the host system's CPU. In addition, storage devices complying with Opal specifications are self-encryption devices. Opal specifications also feature boot authentication. When the drive is being accessed, the shadow MBR will request the drive password at boot. The drive will only unlock and decrypt if the correct password is supplied. The other feature is LBA-specific permissions. Users are assigned different permissions for LBA ranges created by the device administrator. Each LBA range is password-protected and can only be accessed by users with the correct key to perform permitted actions (read/write/erase). 6.3 Thermal Sensor Apacer Thermal Sensor is a digital temperature sensor with serial interface. By using designated pins for transmission, storage device owners are able to read temperature data. 6.4 Thermal Throttling Thermal throttling can monitor the temperature of the SSD equipped with a built-in thermal sensor via S.M.A.R.T. commands. This method can ensure the temperature of the device stays within temperature limits by drive throttling, i.e. reducing the speed of the drive when the device temperature reaches the threshold level, so as to prevent overheating, guarantee data reliability, and prolong product lifespan. When the temperature exceeds the maximum threshold level, thermal throttling will be triggered to reduce performance step by step to prevent hardware components from being damaged. Performance is only permitted to drop to the extent necessary for recovering a stable temperature to cool down the device’s temperature. Once the temperature decreases to the minimum threshold value, transfer speeds will rise back to its optimum performance level. 12 © 2021 Apacer Technology Inc. 6.5 End-to-End Data Protection End-to-End Data Protection is a feature implemented in Apacer SSD products that extends error control to cover the entire path from the host computer to the drive and back, and that ensures data integrity at multiple points in the path to enable reliable delivery of data transfers. Unlike ECC which does not exhibit the ability to determine the occurrence of errors throughout the process of data transmission, End-to-End Data Protection allows SSD controller to identify an error created anywhere in the path and report the error to the host computer before it is written to the drive. This errorchecking and error-reporting mechanism therefore guarantees the trustworthiness and reliability of the SSD. 6.6 CoreGlacierTM In many applications, SSDs are subject to challenging conditions. If the working environment is already hot, and the SSD’s operation causes it to increase in temperature as well, the result could be damage to the hardware or corrupted data. In cases like this, leading industrial manufacturers know to turn to Apacer. Apacer developed CoreGlacier, a heatsink that distributes dissipation in isolated components with no thermal diffusion, to prevent heat-related damage from occurring. 13 © 2021 Apacer Technology Inc. 7. Software Interface 7.1 Command Set Table 7-1 summarizes the commands supported by PV210-M280. Table 7-1 Admin Commands Opcode Command Description 00h Delete I/O Submission Queue 01h Create I/O Submission Queue 02h Get Log Page 04h Delete I/O Completion Queue 05h Create I/O Completion Queue 06h Identify 08h Abort 09h Set Features 0Ah Get Features 0Ch Asynchronous Event Request 10h Firmware Activate 11h Firmware Image Download 14h Device Self-test Table 7-2 Admin Commands – NVM Command Set Specific Opcode Command Description 80h Format NVM 81h Security Send 82h Security Receive 84h Sanitize Table 7-3 NVM Commands Opcode Command Description 00h Flush 01h Write 02h Read 04h Write Uncorrectable 05h Compare 08h Write Zeroes 09h Dataset Management 14 © 2021 Apacer Technology Inc. 7.2 S.M.A.R.T. SMART, an acronym for Self-Monitoring, Analysis and Reporting Technology, is an open standard that allows a hard disk drive to automatically detect its health and report potential failures. When a failure is recorded by SMART, users can choose to replace the drive to prevent unexpected outage or data loss. Moreover, SMART can inform users of impending failures while there is still time to perform proactive actions, such as copy data to another device. Table 7-4 SMART (02h) Byte Length Description 0 1 Critical Warning 1-2 2 Composite Temperature (PCB Sensor) 3 1 Available Spare 4 1 Available Spare Threshold 5 1 Percentage Used (Average Erase Count / P/E Cycle Count) 6-31 26 Reserved 32-47 16 Data Units Read 48-63 16 Data Units Written 64-79 16 Host Read Commands 80-95 16 Host Write Commands 96-111 16 Controller Busy Time 112-127 16 Power Cycles 128-143 16 Power On Hours 144-159 16 Unsafe Shutdowns 160-175 16 Media and Data Integrity Errors 176-191 16 Number of Error Information Log Entries 192-195 4 Warning Composite Temperature Time 196-199 4 Critical Composite Temperature Time 200-201 2 Temperature Sensor 1: Controller Temperature 202-203 2 Temperature Sensor 2: PCB Temperature 204-205 2 Temperature Sensor 3: NAND Flash Temperature 206-207 2 Temperature Sensor 4 208-209 2 Temperature Sensor 5 210-211 2 Temperature Sensor 6 212-213 2 Temperature Sensor 7 214-215 2 Temperature Sensor 8 216-511 296 Reserved 15 © 2021 Apacer Technology Inc. Table 7-5 SMART (C0h) Byte Length Description 0-255 256 256-257 2 SSD Protect Mode 258-261 4 Host Read UNC Count 262-265 4 PHY Error Count 266-269 4 CRC Error Count 270-273 4 Total Early Bad Block Count 274-277 4 Total Later Bad Block Count 278-281 4 Max Erase Count 282-285 4 Average Erase Count 286-289 4 Program Fail Count 290-293 4 Erase Fail Count 294-301 8 Flash Write Sector 302-305 4 Total Spare Block 306-309 4 Current Spare Block 310-313 4 Read Retry Count 314-511 210 Reserved Reserved 16 © 2021 Apacer Technology Inc. 8. Electrical Specifications 8.1 Operating Voltage Table 8-1 lists the supply voltage for PV210-M280. Table 8-1 Operating Range Item Range 3.3V ± 5% Supply Voltage 8.2 Power Consumption Table 8-2 lists the power consumption for PV210-M280. Table 8-2 Power Consumption Capacity 240 GB 480 GB 960 GB 1,920 GB Active (mA) 1,475 1,715 1,830 1,850 Idle (mA) 240 250 250 255 Mode Note: *All values are typical and may vary depending on flash configurations or host system settings. **Active power is an average power measurement performed using CrystalDiskMark with 128KB sequential read/write transfers. 17 © 2021 Apacer Technology Inc. 9. Physical Characteristics 9.1 Double Side Figure 9-1 Dimensions – Double Side 9.2 CoreGlacier Figure 9-2 Dimensions – CoreGlacier 18 © 2021 Apacer Technology Inc. 9.3 Net Weight Table 9-1 Net Weight Capacity Net Weight (g ± 5%) 240GB 7.9 480GB 7.9 960GB 8.35 1,920GB 8.96 19 © 2021 Apacer Technology Inc. 10. Product Ordering Information 10.1 Product Code Designations 1 2 3 B 9 2 4 5 6 7 8 9 10 11 12 13 14 15 16 X X 5 X X U . 0 0 1 0 X Code . Code 1-3 (Product Line & form factor) Code 5-6 (Model/Solution) Code 7-8 (Product Capacity) Code 9 (Flash Type & Product Temp) Code 10 (Product Spec) Code 12-14 (Version Number) Code 15-16 (Firmware Version) PCIe M.2 2280 93: PV210 A3: PV210 with TCG Opal 5J: 240GB 5K: 480GB 5L: 960GB 5M: 1920GB G: 3D TLC Standard temperature H: 3D TLC Wide temperature U:Double side M key with Graphene Random numbers generated by system 04: Thermal Sensor OP 05: Thermal Sensor OP + TCG Opal 20 © 2021 Apacer Technology Inc. 10.2 Valid Combinations 10.2.1 Without TCG Opal Capacity Standard Temperature Wide Temperature 240GB B92.935JGU.00104 B92.935JHU.00104 480GB B92.935KGU.00104 B92.935KHU.00104 960GB B92.935LGU.00104 B92.935LHU.00104 1920GB B92.935MGU.00104 B92.935MHU.00104 Capacity Standard Temperature Wide Temperature 240GB B92.A35JGU.00105 B92.A35JHU.00105 480GB B92.A35KGU.00105 B92.A35KHU.00105 960GB B92.A35LGU.00105 B92.A35LHU.00105 1920GB B92.A35MGU.00105 B92.A35MHU.00105 10.2.2 With TCG Opal Note: Valid combinations are those products in mass production or will be in mass production. Consult your Apacer sales representative to confirm availability of valid combinations and to determine availability of new combinations. 21 © 2021 Apacer Technology Inc. Revision History Revision Description Date 0.1 Preliminary release 6/15/2021 1.0 Official release 6/23/2021 22 © 2021 Apacer Technology Inc. Global Presence Taiwan (Headquarters) U.S.A. Apacer Technology Inc. 1F., No.32, Zhongcheng Rd., Tucheng Dist., New Taipei City 236, Taiwan R.O.C. Tel: 886-2-2267-8000 Fax: 886-2-2267-2261 amtsales@apacer.com Apacer Memory America, Inc. 46732 Lakeview Blvd., Fremont, CA 94538 Tel: 1-408-518-8699 Fax: 1-510-249-9551 sa@apacerus.com Japan Europe Apacer Technology Corp. 6F, Daiyontamachi Bldg., 2-17-12, Shibaura, Minato-Ku, Tokyo, 108-0023, Japan Tel: 81-3-5419-2668 Fax: 81-3-5419-0018 jpservices@apacer.com Apacer Technology B.V. Science Park Eindhoven 5051 5692 EB Son, The Netherlands Tel: 31-40-267-0000 Fax: 31-40-290-0686 sales@apacer.nl China India Apacer Electronic (Shanghai) Co., Ltd Room D, 22/FL, No.2, Lane 600, JieyunPlaza, Tianshan RD, Shanghai, 200051, China Tel: 86-21-6228-9939 Fax: 86-21-6228-9936 sales@apacer.com.cn Apacer Technologies Pvt Ltd, 1874, South End C Cross, 9th Block Jayanagar, Bangalore-560069, India Tel: 91-80-4152-9061/62 Fax: 91-80-4170-0215 sales_india@apacer.com 23 © 2021 Apacer Technology Inc.