WM72016-6-DGTR - Ramtron - Datasheet.Live

Preliminary

This is a product that has fixed target specifications but are Ramtron International Corporation

subject to change pending characterization results. 1850 Ramtron Drive, Colorado Springs, CO 80921

(800) 545-FRAM, (719) 481-7000

http://www.ramtron.com

Rev. 1.4

May 2011 Page 1 of 32

WM72016

16Kbit Secure F-RAM Memory with Gen-2 RFID

Access & Serial Port Direct Memory Access

DESCRIPTION

The WM72016 is a RFID transponder IC with

nonvolatile memory employing an advanced

ferroelectric process. A ferroelectric random access

memory, or F-RAM, is nonvolatile and performs

reads and writes like a RAM. It provides reliable data

retention for 20 years while eliminating the

complexities, overhead, and system level reliability

problems caused by EEPROM and other nonvolatile

memories.

Unlike EEPROM‟s, the WM72016 write operations

are zero power – there is no power or speed premium

paid for executing writes into the WM72016 as

compared to read power and speed. Operation of the

memory is fully symmetric: it has an equivalent read

and write range.

The WM72016‟s RFID interface is compatible with

the EPC Class-1 Generation-2 UHF RFID Protocol

for Communications at 860 MHz – 960 MHz,

Version 1.2.0 Specification for RFID Air Interface.

The WM72016 is a two chip configuration offered in

various forms: standard IC package or wafers. All

specifications discussed herein are applicable to the

combined chipset operation.

Figure 1. System Block Diagram

FEATURES

16 Kbit Ferroelectric Nonvolatile RAM

 Organized as 1024 x 16 bits

 Very High Read/Write Endurance (> 1014)

 20-Year Data Retention

 Gamma Stability Demonstrated to > 30 kGy

 Symmetric Read/Write Operation

 Advanced High-Reliability Ferroelectric Process

Interface and Security Features

 EPC Class 1 Gen2 (ISO18000-6C) RFID

Compatible Interface (revision 1.2.0)

 192-Bit Memory: 96-Bit Electronic Product

Code™ (EPC), 32-Bit Access Password, 32-Bit

KILL Password, 64-Bit TID Memory (Factory

Programmed and Locked)

 Inventory, Read, Write and Erase features

 Kill Command

 Block Permalock Command

 Access Command

 UHF carrier frequencies from 860 MHz to 960

MHz ISM band, ASK demodulation

 Tag-to-reader link frequencies up to 640Kbps

 Reader-to-tag asymptotical transmission rates up

to 128Kbps

 Supports FM0 and MMS data encoding formats

 Serial Port Interface

Custom Features

 Stored Address Pointer to Improve Data Write

Speed

 Stored Address Pointer Lock

 Block Write Command

 Variable USER memory block size support

 Interrupt Generation

Ultra Low Power Operation

 Memory Read/Write Sensitivity: < -6 dBm (typ.)

Industry Standard Configurations

 Industrial Temperature -40 C to +85 C

 Bumped Wafers

 8-pin UDFN

WM72016

RFID Tag

with F-RAM

RFID

Reader

(Class-1

Gen-2)

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 2 of 32

PIN CONFIGURATION (UDFN PACKAGE)

Top View

(PCB Layout)

8

7

6

5

1

2

3

4

Ser_clk

Ser_dat1

Ser_dat0

Ser_CS

ANT-

ANT+

Vddr

Vddraw

3.0 mm × 3.0 mm body, 0.65 mm pad pitch

PIN DESCRIPTION

Pin Name

Pin Number

Type

Description

ANT+, ANT-

7, 8

Input

RFID Antenna. Connect to external RFID antenna terminals.

Connect ANT- to external RFID antenna terminal, also acts as

ground.

Ser_clk

1

Input

Serial interface clock

Ser_dat1,

Ser_dat0

2, 3

I/O

Serial interface bi-directional data

Ser_CS

4

I/O

Serial interface bi-directional chip select/interrupt

Vddraw

5

PWR

Power supply input pin. DC supply (2.1V to 3.0V)

Vddr

6

PWR

Power supply output pin. This supply is internally generated via

the RF field. The Vddr and Vddraw pins are tied together for most

applications. Contact the factory for other applications such as

battery assisted systems.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 3 of 32

FUNCTIONAL DESCRIPTION

The WM72016 is a non-volatile memory device with an industry standard UHF RFID interface that enables

processing data in and out of memory as a generic passive RFID transponder. Unlike other transponder ICs,

the WM72016 transponder IC contains high density symmetric read/write F-RAM memory that enables unique

applications of an RFID solution.

When combined with an appropriate antenna design, WM72016 will power up with energy harvested directly

from the RF field. Following an internally generated reset state, the IC configures itself according to pre-

programmed configuration settings that were stored in F-RAM non-volatile memory at wafer probe, packaged

parts test, or end unit transponder personalization at end-user depot. Configuration settings are read out of

memory and applied prior to enabling data transmission in or out of memory.

As specified in the Gen2 standard, the chip receives and processes commands transmitted by the RFID

interrogator (reader). All required and most optional commands are supported. In addition to these,

WM72016 supports a number of custom commands that take advantage of F-RAM‟s unique ultra low power

and symmetrical characteristics.

Referring to Figure 2, the transponder IC‟s consist of an RFID interface, control and authentication logic, F-

RAM memory, and power management unit. The external antenna is connected directly to the RFID interface

where the RF signal is rectified with high efficiency Schottky diode based rectifier. The rectified voltage is

multiplied up within the Schottky array and then regulated to supply power to on-chip resources.

Also included in the RFID Interface is a modulator/demodulator that detects incoming signals and modulates

the input impedance to enable backscattering of returned signals. The control and authentication logic

processes commands to enable access in and out of F-RAM memory.

Figure 2. Block Diagram

Power

Management

RFID

Interface

Control and

Authentication

Logic

F-RAM Array

(16Kb)

External

MCU

(Optional)

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 4 of 32

MEMORY MAP

WM72016‟s memory is partitioned according to the logical and physical mapping shown in the table below.

Table 1: Memory Map

DSPI

Address

Gen-2

Memory Bank

Gen-2

Address

Word

Pointer

(EBV8)

Description

0x000

RESERVED

0x000

0x00

Kill Password[31:16]

0x001

RESERVED

0x001

0x01

Kill Password[15:0]

0x002

RESERVED

0x002

0x02

Access Password[31:16]

0x003

RESERVED

0x003

0x03

Access Password[15:0]

0x004

EPC

0x000

0x00

CRC

0x005

EPC

0x001

0x01

PC

0x006

EPC

0x002

0x02

EPC - Word 0 (MSW)

0x007

EPC

0x003

0x03

EPC - Word 1

0x008

EPC

0x004

0x04

EPC - Word 2

0x009

EPC

0x005

0x05

EPC - Word 3

0x00A

EPC

0x006

0x06

EPC - Word 4

0x00B

EPC

0x007

0x07

EPC - Word 5 (LSW)

0x00C

EPC

0x008

0x08

EPC - read memory

0x00D

EPC

0x009

0x09

EPC - read memory

0x00E

SERVICE

0x00A

0x0A

RESERVED

0x00F

SERVICE

0x00B

0x0B

RESERVED

0x010

TID

0x000

0x00

TID - Word 0: xE201

0x011

TID

0x001

0x01

TID - Word 1: x6216

0x012

TID

0x002

0x02

TID - Word 2: Serial #1

0x013

TID

0x003

0x03

TID - Word 3: Serial #2

0x014

USER

0x000

0x00

RESERVED

0x015

USER

0x001

0x01

RFU

0x016

USER

0x002

0x02

Control/Status Register

0x017

USER

0x003

0x03

Working Stored Address Register

0x018

USER

0x004

0x04

0x019

USER

0x005

0x05

0x01A

USER

0x006

0x06

USER Memory - Start

0x01B

USER

0x007

0x07

0x0FE

USER

0x0EA

0x816A

0x0FF

USER

0x0EB

0x816B

0x100

USER

0x0EC

0x816C

0x101

USER

0x0ED

0x816D

…

0x1FE

USER

0x1EA

0x836A

0x1FF

USER

0x1EB

0x836B

0x200

USER

0x1EC

0x836C

0x201

USER

0x1ED

0x836D

…

0x3BA

USER

0x3A6

0x8726

0x3BB

USER

0x3A7

0x8727

16k Memory: END

(BLK_SIZE = 1 word/block)

0x3BC

USER

0x3A8

0x8728

0x3BD

USER

0x3A9

0x8729

0x3BE

USER

0x3AA

0x872A

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 5 of 32

DSPI

Address

Gen-2

Memory Bank

Gen-2

Address

Word

Pointer

(EBV8)

Description

…

0x3DA

USER

0x3C6

0x8746

0x3DB

USER

0x3C7

0x8747

16k Memory: END

(BLK_SIZE = 2 words/block)

0x3DC

USER

0x3C8

0x8748

0x3DD

USER

0x3C9

0x8749

0x3DE

USER

0x3CA

0x874A

…

0x3EA

USER

0x3D6

0x8756

0x3EB

USER

0x3D7

0x8757

16k Memory: END

(BLK_SIZE = 4 words/block)

0x3EC

USER

0x3D8

0x8758

0x3ED

USER

0x3D9

0x8759

0x3EE

USER

0x3DA

0x875A

…

0x3F3

USER

0x3DF

0x875F

16k Memory: END

(BLK_SIZE = 8 words/block)

0x3F4

USER

0x3E0

0x8760

0x3F5

USER

0x3E1

0x8761

0x3F6

USER

0x3E2

0x8762

0x3F7

USER

0x3E3

0x8763

16k Memory: END

(BLK_SIZE = 16 words/block)

0x3F8

USER

0x3E4

0x8764

0x3F9

USER

0x3E5

0x8765

16k Memory: END

(BLK_SIZE = 32 words/block)

0x3FA

USER

0x3E6

0x8766

0x3FB

USER

0x3E7

0x8767

(BLK_SIZE > 32 words/block)

0x3FC

USER

0x3E8

0x8768

RESERVED

0x3FD

USER

0x3E9

0x8769

RESERVED

0x3FE

USER

0x3EA

0x876A

RESERVED

0x3FF

USER

0x3EB

0x876B

RESERVED

NOTE: When accessing the memory through the DSPI serial port, care must be taken to ensure that reserved

memory required to store critical parameters for the operation of the device is not altered.

GEN2 WM72016 MEMORY BANKS

The RFID memory banks reside in Ramtron‟s non-volatile F-RAM memory. F-RAM brings many benefits to

the WM72016. The first benefit is the size of the memory itself – 16k-bit, most of which is available in the

USER memory bank. F-RAM‟s impact on the Gen2 protocol is most dramatically seen when writing to

WM72016 memory. Unlike EEPROM memory, no charge pump or memory soak time is required to write to

WM72016 memory resulting in zero time and zero power penalties. The write cycle is completed

immediately, allowing an interrogator to continue writing additional data to memory with no time penalty

incurred due to the memory itself. A comparison between F-RAM and EEPROM memories is shown in Figure

3. The figure shows the minimum number of Gen2 instructions required to perform a SELECT, INVENTORY,

and ACCESS sequence of commands to write a data word to memory. The same interrogator command

sequence is transmitted to the WM72016 and an EEPROM-based RFID. The effect of the EEPROM time

penalty is shown within the context of the protocol.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 6 of 32

INTERROGATOR

TAG

MaxArias Write Cycle

QURY

(240u)

SELECT

(385u) ACK

(175u) REQRN

(345u)

EPC

(228u)

WRITE

(495u)

RN

(53u) HANDLE

(78u) WR_OK

(80u)

REQRN

(345u)

RN16

(78u)

EEPROM write delay!

Charge pump & EE soak time

EEPROM-based Write Cycle

4ms

Figure 3. Gen2 Memory Write Cycle Comparison: F-RAM vs. EEPROM Memories

RESERVED: KILL Password:

The kill password provides a mechanism to permanently disable the WM72016 RFID from responding to any

and all Gen2 interrogator commands. The mandatory KILL command can be issued by a RFID interrogator in

either the OPEN or SECURED states. The WM72016 is permanently killed through a four-instruction

sequence of REQRN and KILL commands as detailed in the Gen2 standard. The KILL password is a 32-bit

value stored as 2 16-bit data words in reserved memory. The most significant KILL password is stored in

reserved memory bank address 0x00 with the least significant word stored in reserved memory bank address

0x01. The kill function can be permanently disabled by setting both KILL password words to 0x0000, and

permanently locking the KILL password in the reserved memory bank. Once the kill password has been set, it

should be permanently locked using the LOCK command. The WM72016 is shipped from the factory with the

kill password memory unlocked. The kill state of the device only affects the Gen2 RFID processor – the DSPI

serial port will continue to function normally.

RESERVED: ACCESS Password:

The access password provides a security mechanism to prevent unauthorized RFID interrogators from writing

to WM72016 memory. Non-zero access passwords require the WM72016 be placed in the SECURED state

prior to writing to it. This is accomplished through a four-instruction sequence of REQRN and ACCESS

commands as described in the Gen2 standard. An access password with a value of zero requires no

authentication prior to writing to WM72016 memory. The ACCESS password is a 32-bit value stored as two

16-bit data words in reserved memory. The most significant ACCESS password is stored in reserved memory

bank address 0x02 with the least significant word stored in reserved memory bank address 0x03. Once the

access password has been set, it should be permanently locked using the LOCK command. The WM72016 is

shipped from the factory with the access password memory unlocked. The value of the access password has no

effect on the functionality of the DSPI serial port.

EPC Memory Bank:

The EPC memory bank accommodates 8 words: 1 protocol control (PC) word, a 6-word (96-bit) memory space

for an EPC identifier, and a 1-word CRC. The CRC word is calculated as part of the WM72016 power-on

initialization routine and written into the EPC memory bank address 0x00. The PC and 6-word EPC identifier

are completely programmable. The Protocol Control field is shown in Figure 4.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 7 of 32

00110 000000000 01

DEFAULT

Numbering System Identifier

NSI Type

Extended Protocol Control

User Memory identifier

EPC Identifier Word Length

LEN NSIXPC NTUMI

15 11 910 8 7 0bit

PROTOCOL CONTROL WORD

Figure 4. EPC Protocol Control Word

The five most significant bits of the PC indicates the size of the EPC identifier in words – for a 96-bit (6-word)

EPC identifier, the PC should be programmed to 0b0011_0xxx_xxxx_xxxx. The LEN parameter of the PC

word may not be greater than 0b00110 – a LEN parameter of 0b00000 has an EPC identifier length of zero

words resulting in only the PC and CRC words when WM72016 is acknowledged. The UMI bit (User

Memory Identifier) is asserted to a logic one by WM72016 and mapped to bit 10 of the PC word. In the event

the host writes a logic zero to the UMI bit, the memory location will be written with a logic zero, however the

backscattered EPC identifier will assert the UMI bit to a logic one which is also used in the calculation of the

CRC. WM72016 does not support extended protocol control and should be written with a logic zero. PC word

bits 8 down to 0 of the PC word are factory-initialized to zero. The WM72016 is shipped from the factory with

the EPC memory bank unlocked.

TID Memory Bank:

The TID memory bank consists of 4 words (64 bits), and is defined as shown in Table 2. The TID memory

bank is permanently locked at the factory and obeys the ISO/IEC 15963 numbering convention.

Table 2: TID memory Bank Fields

Class Identifier MDID[11:4]

MDID[3:0] TMN[11:0]

ID[31:16]

ID[15:0]

0 7 8 15

16 20 31

32 47

48 63

19

Figure 5. TID Memory Bank Fields

Bit Field

Value

(hex)

Description

00h – 07h

E2

ISO/IEC 15963 class-identifier

08h – 13h

016

Mask-Designer Identifier (MDID) – Ramtron International

14h – 1Fh

216

Tag model number

20h – 3Fh

32-bit unique identifier

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 8 of 32

USER Memory Bank:

The USER memory bank comprises two special-function control words, factory-reserved words, and up to 993

available memory locations. Refer to Table 1 for detail on the WM72016 memory structure. The USER

memory bank may be completely locked through the LOCK command. WM72016 also supports the

BLOCKPERMALOCK command providing the ability to lock contiguous words of USER memory, with word

block sizes as small as a single word up to a maximum block size of 128 words. The USER memory bank

ships from the factory completely unlocked.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 9 of 32

TAG-TO-READER DATA ENCODING

The WM72016 supports both encoding formats defined in the Gen2 standard:

 FM0 baseband (FM0)

 Miller modulation of a subcarrier (MMS)

Data encoding is performed in the WM72016 as described in the Gen2 standard. A FM0 data symbol is

transmitted with period T which is defined by the tag-to-reader link frequency. The difference between a logic 0

and a logic 1 is defined by an additional mid-bit transition for a logic 0 as shown below in Figure 6. Data

encoding using Miller modulation of a subcarrier (MMS) is further defined by a rate parameter M that defines the

number of link frequency cycles per data bit: 2, 4, or 8, resulting in data encoding defined as MMS2, MMS4, or

MMS8 respectively. MMS data encoding results in a phase inversion of the sub-carrier frequency when one of

the following conditions occurs:

 At the mid-bit of a logic 1 data bit, or

 At the bit-boundary of two consecutive logic 0s.

The following set of four figures depicts the data bit values “00”, “01”, “10” and “11” for FM0 and MMS data

encoding formats. The same link frequency is shown for all cases, however the MMS parameter M lengthens the

baseband bit period by 2, 4, or 8 as shown in Figure 7, Figure 8, and Figure 9.

0 T 2T

11

10

01

00

Figure 6. FM0 Data Encoding

0 2T 4T

11

10

01

00

Figure 7. MMS2 Data Encoding

11

10

01

00

0 4T 8T

Figure 8. MMS4 Data Encoding

11

10

01

00

0 8T 16T

Figure 9. MMS8 Data Encoding

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 10 of 32

CONTROL/STATUS REGISTER

Accessing the unique features of WM72016 is accomplished through the Control/Status register in F-RAM

non-volatile memory. The register is located at physical address 0x016 or USER memory address 0x002.

The Control/Status word register is organized as shown in Table 3 below. Care should be exercised when

writing the Control/Status register word if it is to remain unlocked.

LCK PLCK RFU BW

EN BLKSIZ WRP WRP

EN ALCK AINC

Figure 10. Control/Status Register

Table 3: Control/Status Word Register

Bit

Mnemonic

Function

Initial

Value

15

LOCK

Memory locking of this register.

LOCK

PERMALOCK

DESCRIPTION

0

Register unlocked

0

1

Register permanently unlocked

1

0

Register writeable only from the

SECURED state

1

Register permanently locked

0

14

PERMALOCK

0

13

RFU

Reserved for future use

0

12

RFU

Reserved for future use

0

11

RFU

Reserved for future use

0

10

RFU

Reserved for future use

0

9

RFU

Reserved for future use

0

8

RFU

Reserved for future use

0

7

BLKWREN

Enables use of the custom command BLOCKWRITE.

1

6

BLKSIZ[2]

USER memory block size.

BLKSIZ[2:0]

# words

BLKSIZ[2:0]

# words

000

1

100

16

001

2

101

32

010

4

110

64

011

8

111

128

1

5

BLKSIZ[1]

1

4

BLKSIZ[0]

0

3

WRPSTAT

Indicates if the Working Stored Address has wrapped.

Logic State

Description

0

Wrapping has not occurred

1

Wrapping has occurred at least once

0

2

WRPEN

Enables wrapping of the Working Stored Address when it reaches the

top of logical memory.

Logic State

Description

0

DISABLE memory wrapping

1

ENABLE memory wrapping.

0

1

AUTOLOCK

Enable Automatic Locking of all user memory between the start of USER

memory and the Working Stored Address register.

Logic State

Description

0

Auto-lock DISABLED

1

Auto-lock ENABLED

0

AUTOINCR

Enable the Working Stored Address word to Auto-Increment when

performing an unaddressed write cycle.

Logic State

Description

0

DISABLE auto-increment of stored address register

1

ENABLE auto-increment of stored address register

0

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 11 of 32

Upon power up, WM72016‟s control logic reads the control word out of memory and configures itself

accordingly. User applications may change the control word as needed providing the register has not been

permanently locked. The Control/Status word may be read by the application at any time.

Register Locking: The LOCK and PERMALOCK control bits are implemented in a similar manner as locking

bits used for Gen2 memory bank locking with the exception that the lock control bits are incorporated into the

register they are locking. As such, attention needs to be placed on how the contents of the Control/Status word

are written when the register is not completely unlocked.

Table 4: Control/Status Word Locking

LOCK

PERMA-

LOCK

Description

0

Register unlocked. All control bits, including the LOCK and PERMALOCK bits can

be written to from the OPEN or SECURED states.

0

1

Register permanently unlocked. All control bits can be written from the OPEN or

SECURED states. The LOCK and PERMALOCK bits must be set to logic values 0

and 1 respectively when writing the Control/Status word.

1

0

Register locked. All control bits can be written to only from the SECURED state.

The register cannot be written to in the OPEN state. The LOCK and PERMALOCK

bits must be set to logic values 1 and 0 respectively when writing the Control/Status

word.

1

Register permanently locked. The register cannot be written in any circumstance.

Block Write Enable: The BLKWREN control bit enables usage of the WM72016 custom command

BLOCKWRITE. The BLKWREN parameter is internally updated during power-on WM72016 initialization.

In the event the host application toggles the state of BLKWREN either through the Gen2 or serial interfaces, a

WM72016 power cycle is required to reflect the change.

Block Size: The 3 BLKSIZ[2:0] control bits adjust the USER memory block sizes as shown in Table 5. This

provides a host application the ultimate flexibility in determining a balance between the USER memory

requirements and the granularity of the number of USER memory words per block. The larger the granularity

of the block size, the greater amount of available USER memory. The effect of the block size on available

USER memory is shown in Table 1. The total number of USER memory words available as a function of the

block size is shown in Table 5 below. It is of utmost importance that the 3-bit block size is not modified once

set, which would otherwise result in corruption of block permalock status bits.

Table 5: Available USER Memory

Memory

BLKSIZ

Words/Block

Free USER Memory

(words)

16k

000

1

931

16k

001

2

963

16k

010

4

979

16k

011

8

987

16k

100

16

991

16k

101

32

993

16k

110

64

993

16k

111

128

993

Wrap Status: The WRPSTAT status bit is asserted to a logic one when the following conditions are true:

(a) WRPEN=1, AUTOINCR=1 and AUTOLOCK=0,

(b) The contents of the Working Stored Address register address the last USER memory location, and

(c) An unaddressed WRITE command is received.

The WRPSTAT can be cleared by the RFID interrogator by writing a logic zero to the WRPSTAT bit.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 12 of 32

Wrap Enable: Asserting the WRPEN control bit to a logic one enables the USER memory wrapping feature.

The wrap enable feature allows the stored address pointer to wrap back to the factory-set initial stored address

value of 0x006. In this manner, the WM72016 memory acts as a circular buffer. Clearing the WRPEN control

bit disables wrapping resulting in a write-once memory. In this case, when the Working Stored Address

reaches the end of user memory, no additional unaddressed write cycles will be possible. The WRPEN and

AUTOLOCK control bits are mutually exclusive – only one of the two control bits may be asserted at any

given time.

Auto Lock Enable: Asserting the AUTOLOCK control bit to a logic one enables memory locking of the USER

memory span between the start of USER memory and the Working Stored Address. The AUTOLOCK and

WRPEN control bits are mutually exclusive – only one of the two control bits may be asserted at any given

time. The automatic locking feature can only be used when AUTOINCR is asserted to a logic one.

Auto Increment: Asserting AUTOINCR control bit to a logic one enables the Working Stored Address

increment function. Upon receiving an unaddressed write cycle, the WM72016 increments the pointer stored

in the Working Stored Address register to point to the next free memory location then writes the cover-coded

data word to the respective memory location. This functionality removes any requirement for a RFID

interrogator to determine where free USER memory is located and manipulating the memory pointer itself.

WORKING STORED ADDRESS

To better utilize the F-RAM‟s fast write capability, memory has been architected using an optional Working

Stored Address register. The stored address function enables automation of the storage of large blocks of user

data, such as pedigree or tracking information. This feature enables a RFID interrogator the ability to use a

standard Gen2 WRITE command using a designated address of 0x3FFF (0xFF7F EBV-formatted) as a redirect

pointer to use the contents of the Working Stored Address register – this is referred to as an unaddressed write

(UNADDR_WRITE). The Working Stored Address is a USER memory address pointer used to address the

first available USER memory data word as shown in Figure 12. The Working Stored Address is a read/write

register located at address 0x003 in USER memory. It may be used to address USER memory only – it is an

address pointer to a memory location within the USER memory bank and cannot be used to address other

memory banks or memory regions in the WM72016. It may be manually updated by simply writing to USER

memory address 0x003 or will automatically increment when the AUTOINCR control bit in the Control/Status

register is asserted to a logic one and an unaddressed write command is received.

LCK INIT

EN

RFU ADDR[9:0]PLCK

Figure 11. Working Stored Address Register

Table 6: Working Stored Address – Bit Definitions

Bit

Mnemonic

Function

Initial

Value

15

LOCK

Memory locking of this register.

LOCK

PERMALOCK

DESCRIPTION

0

Register unlocked

0

1

Register permanently unlocked

1

0

Register writeable only from the

SECURED state

1

Register permanently locked

0

14

PERMALOCK

0

13:11

RFU

Reserved for future use

0

10

INITEN

When asserted to a logic ‘1’, sets the contents of the Initial Stored

Address register with the value defined in the 10-bit address field in bits

9 through 0 written to this register using a Gen2 write instruction.

0

9:0

ADDR

Working stored address pointer

006

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 13 of 32

Working Stored

Address Pointer

Gen-2 Memory

Bank

Gen-2 Address

Description

RESERVED

0x000 - 0X003

RESERVED - passwords

MEMORY UNAVAILABLE

EPC

0x000 - 0x009

EPC

SERVICE

0x00A

RESERVED

SERVICE

0x00B

RESERVED

TID

0x000 - 0x003

TID

USER

0x000

RESERVED

USER

0x001

RFU

USER

0x002

Control/Status Register

USER

0x003

Working Stored Address Register: 0x0006

USER

0x004

USER

0x005



USER

0x006

USER Memory - START

AVAILABLE

MEMORY

USER

0x007

USER

0x008

USER

…

USER

USER Memory - END

Figure 12. USER Memory Bank: Working Stored Address Register

The syntax for an unaddressed write command is shown in Figure 13 below. All protocol requirements

governing implementation of a WRITE command also apply to the UNADDR_WRITE command.

WRITE

(0xC3) Membank

(0b11) WordPtr

(0xF7FF) 16-bit Data (cover-coded)

(0xNNNN)Handle

(0xHHHH)CRC-16

(0xCCCC)

Figure 13. Unaddressed Write Syntax

Upon reception of a valid UNADDR_WRITE command, the WM72016 examines the state of the AUTOINCR

control bit:

AUTOINCR=0: The 16-bit data word cover-coded in the unaddressed write instruction is written to the

memory address stored in the Working Stored Address register. The contents of the Working Stored

Address register remain unaltered. To avoid the memory being over-written, the Working Stored Address

register must be manually updated.

AUTOINCR=1: The Working Stored Address register is incremented by one, followed by the 16-bit data

word being written to memory. The contents of the Working Stored Address register will reflect the

memory address just written to. A single unaddressed write cycle is shown in Figure 14 with the

AUTOINCR control bit set to a logic one. The Working Stored Address has an initial value of 0x0006 as

shown in Figure 12. An unaddressed write cycle (with AUTOINCR=1) increments the address pointer to

0x0007 followed by a write cycle to the WM72016 memory resulting in data word DATA0 being written

to USER memory address 0x007. Figure 15 depicts an additional seven discrete unaddressed write cycles

(REQRN command for cover-coding not shown). Prior to unaddressed write commands, the Working

Stored Address has a memory address of addrn. An unaddressed write command with data payload

DATAn is written to addrn+1; the following unaddressed write command with data payload DATAn+1 is

written to addrn+2, and so on. Upon completion of the final unaddressed write command, the memory

pointer contents of the Working Stored Address will be addrn+8, reflecting the memory address of the last

unaddressed write cycle. In this manner, the RFID interrogator does not have to read the memory

contents to discern the next available memory location. This substantially reduces the time required

in the RF field yielding greater throughput of a population of tags.

The Working Stored Address pointer will be factory-initialized to the start of USER memory then

managed by the memory controller or the host application as required.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 14 of 32

Working Stored

Address Pointer

Gen-2 Memory

Bank

Gen-2 Address

Description

RESERVED

0x000 - 0X003

RESERVED - passwords

MEMORY UNAVAILABLE

EPC

0x000 - 0x009

EPC

SERVICE

0x00A

RESERVED

SERVICE

0x00B

RESERVED

TID

0x000 - 0x003

TID

USER

0x000

RESERVED

USER

0x001

RFU

USER

0x002

Control/Status Register

USER

0x003

Working Stored Address Register: 0x0007

USER

0x004

USER

0x005



USER

0x006

USER Memory - START

AVAILABLE

MEMORY



USER

0x007

UNADDR_WRITE: DATA0

USER

0x008

USER

…

USER

USER Memory - END

Figure 14. Single Unaddressed Write Cycle, AUTOINCR=1

Working Stored

Address Pointer

Gen-2 Memory

Bank

Gen-2 Address

Description

RESERVED

0x000 - 0X003

RESERVED - passwords

MEMORY UNAVAILABLE

EPC

0x000 - 0x009

EPC

SERVICE

0x00A

RESERVED

SERVICE

0x00B

RESERVED

TID

0x000 - 0x003

TID

USER

0x000

RESERVED

USER

0x001

RFU

USER

0x002

Control/Status Register

USER

0x003

Working Stored Address Register: 0x000E

USER

0x004

USER

0x005



USER

0x006

USER Memory - START

AVAILABLE MEMORY



USER

0x007

UNADDR_WRITE: DATA0



USER

0x008

UNADDR_WRITE: DATA1

USER

0x009

UNADDR_WRITE: DATA2

USER

0x00A

UNADDR_WRITE: DATA3

USER

0x00B

UNADDR_WRITE: DATA4

USER

0x00C

UNADDR_WRITE: DATA5

USER

0x00D

UNADDR_WRITE: DATA6



USER

0x00E

UNADDR_WRITE: DATA7

USER

0x00F

USER

0x010

USER

0x011

…

USER Memory - END

Figure 15. Multiple Unaddressed Write Cycles, AUTOINCR=1

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 15 of 32

INITIAL STORED ADDRESS

The Initial Stored Address is a preset address pointer that is loaded into the Working Stored Address when a

memory wrap occurs after an unaddressed write command is executed. A memory wrap only occurs if the

WRPEN control bit is asserted to a logic one and the AUTOLOCK control bit is cleared to a logic zero in the

Control/Status register and the Working Stored Address points to the last free memory location in the USER

memory bank (last memory location depends on the set block size).

The contents of the Initial Stored Address may be altered by setting the INITEN bit to a logic one through a

Gen2 write cycle to the Working Stored Address register – refer to Table 6 above. When the INITEN control

bit is set during a write cycle, the contents of the Working Stored Address register in USER memory 0x003 are

not affected.

Use of an Initial Stored Address register provides flexibility when using the wrap enable feature of WM72016.

It may be set to the start of USER memory, allowing the entire USER memory bank to be utilized.

Alternatively, it may be set to a higher memory address within the USER memory bank. This mechanism

would provide for a static USER memory bank and a dynamic USER memory bank as shown in Figure 16

below. In the example shown in Figure 16, the Working Stored Address points to address 0x3F8 after having

written user_log_data[n] with an unaddressed write command. The subsequent unaddressed write cycle will

increment (wrap) the Working Stored Address to the value defined by the Initial Stored Address, defined in this

example as 0x000A, and write the value user_log_data[n+1] to USER memory bank 0x00A, over-writing the

previous data contents user_log_data[0]. In the example shown, four memory locations are used for static

memory, or memory that will not be over-written when a wrap condition has occurred.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 16 of 32

Working Stored

Address Pointer

Gen-2

Memory

Bank

Gen-2

Address

Description

RESERVED

0x000 - 0X003

RESERVED - passwords

MEMORY UNAVAILABLE

EPC

0x000 - 0x009

EPC

SERVICE

0x00A

RESERVED

SERVICE

0x00B

RESERVED

TID

0x000 - 0x003

TID

USER

0x000

RESERVED

USER

0x001

RFU

USER

0x002

Control/Status Register

USER

0x003

Working Stored Address Register: 0x03F8

USER

0x004

USER

0x005



USER

0x006

user_static_data0

STATIC



USER

0x007

user_static_data1



USER

0x008

user_static_data2

USER

0x009

user_static_data3

Initial Stored Address

USER

0x00A

user_log_data[0], user_log_data[n+1]

DYNAMIC

USER

0x00B

user_log_data[1]

USER

0x00C

…

USER

0x00D

…



USER

0x00E

…

USER

0x00F

…

USER

0x010

…

USER

0x011

…

USER

0x3F7

user_log_data[n-1]



USER

0x3F8

user_log_data[n]

Figure 16. Initial Stored Address Example – Block Size = 128 words/block

The Initial Stored Address is factory-initialized with a value of 0x0006 (USER memory bank address 0x006).

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 17 of 32

SUPPORTED COMMANDS

The WM72016 supports the following Select, Inventory, and Access commands as described in the

EPCglobal class 1 generation 2 UHF RFID Specification. Please refer to the referenced document for detailed

descriptions of these commands.

 Select

 Query

 QueryAdjust

 QueryRep

 ACK

 NAK

 Req_RN

 Read

 Write

 Kill

 Lock

 Access

 BlockWrite *

 BlockPermalock

MAXARIAS GEN2 CUSTOM COMMAND: BLOCKWRITE

The WM72016 supports a customized version of the BLOCKWRITE command to support unique features

within the device. The BLOCKWRITE command optional feature is enabled by asserting the BLKWREN

control bit in the Control/Status register to a logic one, after which the WM72016 will require a power cycle to

initialize itself. To support other features within the WM72016, the BLOCKWRITE command uses the

address stored in the Working Stored Address register. The address pointer passed in the BLOCKWRITE

command is the physical address 0x3FFF (EBV formatted address = 0xF7FF), representing the same address

used for unaddressed write cycles. A single BLOCKWRITE command carries a maximum data payload of

127 words. BLOCKWRITE commands with data payloads greater than 127 words may optionally be written

to unlocked memory, however WM72016 will not acknowledge the BLOCKWRITE command with a success

message. In this event, the host interrogator may perform one or more READ cycles to verify USER memory

data contents.

Prior to transmitting a BLOCKWRITE command, the interrogator must set the Working Stored Address

register through a standard Gen2 WRITE command. The BLOCKWRITE command is shown in Figure 17

below.

BLKWRITE

(0xC7) Membank

(0b11) WordPtr

(0xF7FF) Data

(xNN × 16-bit data) Handle

(0xHHHH)CRC-16

(0xCCCC)

WordCnt

(0xNN)

Figure 17. Block Write Syntax

BLOCKWRITE commands do not support the auto-increment feature used for UNADDR_WRITE commands.

As such, the Working Stored Address must be manually updated by the host interrogator and will not be altered

by a BLOCKWRITE command. When using the streaming capabilities of the BLOCKWRITE command, care

should be taken to consider the logic state of the AUTOINCR control bit. As with UNADDR_WRITE

commands, the Working Stored Address register is incremented prior to writing data to memory when

AUTOINCR=1 affecting the first USER memory address written to. Figure 18 shows an 8-word

BLOCKWRITE command with AUTOINCR=0; Figure 19 shows a BLOCKWRITE command with

AUTOINCR=1. In the respective figures, when AUTOINCR=0, data is written starting at the address defined

by the Working Stored Address register – 0x006; when AUTOINCR=1, data is written starting at the next free

address defined by the contents of the Working Stored Address incremented by one, or 0x007. It is important

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 18 of 32

to note that in both cases, the value stored in the Working Stored Address register does not change for a

BLOCKWRITE command – in the example shown, it remains at a value of 0x006.

Working Stored

Address Pointer

Gen-2 Memory

Bank

Gen-2 Address

Description

RESERVED

0x000 - 0X003

RESERVED - passwords

MEMORY UNAVAILABLE

EPC

0x000 - 0x009

EPC

SERVICE

0x00A

RESERVED

SERVICE

0x00B

RESERVED

TID

0x000 - 0x003

TID

USER

0x000

RESERVED

USER

0x001

RFU

USER

0x002

Control/Status Register

USER

0x003

Working Stored Address Register: 0x0006

USER

0x004

USER

0x005



USER

0x006

BLKWRITE: DATA0

AVAILABLE MEMORY



USER

0x007

BLKWRITE: DATA1



USER

0x008

BLKWRITE: DATA2

USER

0x009

BLKWRITE: DATA3

USER

0x00A

BLKWRITE: DATA4

USER

0x00B

BLKWRITE: DATA5

USER

0x00C

BLKWRITE: DATA6

USER

0x00D

BLKWRITE: DATA7



USER

0x00E

USER

0x00F

…

USER Memory - END

Figure 18. BLOCKWRITE Command: AUTOINCR=0

Working Stored

Address Pointer

Gen-2 Memory

Bank

Gen-2 Address

Description

RESERVED

0x000 - 0X003

RESERVED - passwords

MEMORY UNAVAILABLE

EPC

0x000 - 0x009

EPC

SERVICE

0x00A

RESERVED

SERVICE

0x00B

RESERVED

TID

0x000 - 0x003

TID

USER

0x000

RESERVED

USER

0x001

RFU

USER

0x002

Control/Status Register

USER

0x003

Working Stored Address Register: 0x0006

USER

0x004

USER

0x005



USER

0x006

USER Memory - START

AVAILABLE MEMORY



USER

0x007

BLKWRITE: DATA0



USER

0x008

BLKWRITE: DATA1

USER

0x009

BLKWRITE: DATA2

USER

0x00A

BLKWRITE: DATA3

USER

0x00B

BLKWRITE: DATA4

USER

0x00C

BLKWRITE: DATA5

USER

0x00D

BLKWRITE: DATA6



USER

0x00E

BLKWRITE: DATA7

USER

0x00F

…

USER Memory - END

Figure 19. BLOCKWRITE Command: AUTOINCR=1

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 19 of 32

DUAL SERIAL PERIPHERAL INTERFACE (DSPI)

The WM72016 employs a dual serial peripheral interface (DSPI) bus providing a serial communication port to

a host microcontroller for the purpose of directly reading and writing memory. The interface uses four pins as

shown in Table 7.

Table 7: DSPI Interface

Signal Name

Direction

Description

CS

INPUT/OUTPUT

Chip Select

D1

INPUT/OUTPUT

Data bit 1

D0

INPUT/OUTPUT

Data bit 0

CLK

INPUT

Clock

A single DSPI access cycle is composed of a 16-bit instruction word and a 16-bit data word as shown in Figure

20. A DSPI read/write cycle is initiated by asserting CS high followed by 16 clock cycles. The host drives the

first set of 8 clock cycles to write 2 data bytes comprising an instruction word – the second set of 8 clock

cycles are required for the 16-bit data word. Command and data bits are interleaved across two DSPI data

signals in such a manner that odd numbered bits are driven on one data signal while even numbered bits are

driven on the other data signal as shown in section DSPI Serial Port Timing. This results in a 16-bit word

transfer on the D0 and D1 signals every 8 clock cycles.

INSTR_WORD

DATA_WORD

CS

CLK

D0

D1

Figure 20. DSPI Cycle

WRITE CYCLES

DSPI write cycles are detailed in the DSPI Serial Port Timing section. The host microcontroller drives all four

DSPI signals for the duration of the cycle. The WM72016 uses the rising edge of CLK to shift in the 2 data

bits presented on the D1 and D0 signals. The host microcontroller shall obey the timing constraints detailed in

Table 10. The host microcontroller asserts the 2 data bits prior to the rising edge of CLK. The host

microcontroller shifts the instruction word with the first set of 8 CLK cycles and shifts the data word on the

second set of 8 CLK cycles. The write cycle is terminated by clearing the CS signal.

READ CYCLES

SPI read cycles are detailed in the DSPI Serial Port Timing section. The host microcontroller shall transmit the

instruction word in the same manner as done for DSPI write cycles. The WM72016 uses the rising edge of

CLK to shift in the 2 data bits presented on the D1 and D0 signals. Once the instruction word has been

completely transmitted and the CLK signal has been cleared to a logic zero, the host shall tri-state the D1 and

D0 signals allowing the WM72016 to drive the data bits for the remainder of the read cycle. The WM72016

shall shift a pair of data bits on D1 and D0 on the rising edge of CLK – the host shall use the falling edge of

CLK to capture the data pair into its shift register. The host shall transmit a total of 8 CLK cycles to receive

the entire data word, after which it clears the CS to a logic zero to terminate the read cycle.

The syntax of the instruction word is detailed in Table 8.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 20 of 32

Table 8: DSPI Instruction Word

Signal

Mnemonic

Bit

Description

Read/Write

RW

15

Read/Write Control. RW is asserted to logic „1‟ for a read

cycle. RW is cleared to logic „0‟ for write cycle.

Opcode

OP

14..10

Instruction opcode.

Address

A

9..0

MaxArias physical memory address.

The read/write bit (RW) sets the data direction of the subsequent data word(s). On write cycles, the host

continues to drives the DSPI bus with data words. The MaxArias WM72016 uses the rising edge of CLK to

register data presented on D0 and D1. On read cycles, the host drives the DSPI bus with the instruction word,

then tri-states the D0 and D1 signals while receiving data from MaxArias memory.

The opcode (OP) parameter is a 5-bit value that can take on the following values shown in Table 9.

Table 9: DSPI Opcode Values

Mnemonic

OPCODE[4:0]

Description

NORM

11001

Normal read/write instruction.

INTEND

11101

Interrupt end instruction.

-

Others

RESERVED

Two instruction opcodes available in the WM72016 are:

1. NORM – normal opcode for all read/write instructions, and

2. INTEND – DSPI serial port control register opcode.

The address parameter of the DSPI instruction word is a 10-bit value capable of addressing the entire

WM72016 1024-word physical memory. Physical memory addressing is shown in the left-most column in

Table 1. In the event that memory arbitration is required between the RFID and serial interfaces, the RFID

interface will always have priority. The only exception to this rule is WM72016 interrupt generation, during

which time the serial port has full control over the memory. Care needs to be taken to ensure that reserved

memory required to store critical parameters for the operation of the device are not altered.

DSPI Data Streaming

Data may be streamed into the WM72016 (write cycles) or out of WM72016 (read cycles) using a single

instruction word and 2 or more consecutive data words as shown in Figure 21. The example shown in the

figure depicts n+1 data words. The host microcontroller initiates the read or write instruction in the same

manner as detailed earlier: the CS signal is asserted, followed by 8 CLK cycles to shift the instruction word

and 8 CLK cycles to shift the data word. From this point forward, each set of 8 CLK cycles is used to read or

write the next WM72016 memory location. While the CS signal remains at a logic one, the WM72016

automatically increments an internal address pointer after every data word cycle has completed. The state of

the AUTOINCR bit in the Control/Status register and the contents of the Working Stored Address have no

impact on DSPI data streaming. Likewise, AUTOINCR and the Working Stored Address register are not

affected by DSPI serial port data streaming. The data streaming cycle is terminated once CS has been cleared

to a logic zero. The DSPI streaming capability removes the requirement for multiple instruction words, greatly

improving bandwidth requirements.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 21 of 32

tWD tCSH

tHD tCLK

tSU

tCSD

d14 d12 d10 d8 d6 d4 d2 d0OP4 OP2 OP0 a8 a6 a4 a2 a0

d15 d13 d11 d9 d7 d5 d3 d1WR OP3 OP1 a9 a7 a5 a3 a1

CS

D0

D1

CLK

Figure 21. DSPI Write Cycle Detail

Note: In the event of a simultaneous memory access, the RFID request will take priority over the

secondary DSPI serial interface.

MICROCONTROLLER INTERRUPTS

The WM72016 is capable of generating interrupts initiated by a RFID interrogator to a microcontroller on the

serial port. Interrupt generation provides a mechanism to alert a host microcontroller that a RFID interrogator

is present and to take control of the memory with no possibility of interruption from the RFID interface.

During an interrupt, all RFID commands are disregarded until an INTEND DSPI command is received to

terminate the interrupt and return control back to the RFID interface.

An interrupt is generated from the WM72016 to the host by writing two standard Gen2 write cycles to USER

memory addresses 0x004 and 0x005. The XOR operation of the two data words written to the two respective

addresses must equal 0x1234. As with all Gen2 write commands, the WM72016 must be in the OPEN or

SECURED state prior to executing the write command sequence. Should the WM72016 RFID have a non-

zero ACCESS password, the device must be transitioned to the SECURED state by correctly accessing the tag

with the device‟s ACCESS password. The RFID interrogator then transmits two cover-coded WRITE

commands to USER memory addresses 0x004 and 0x005 whose two data words when XORed together result

in a value of 0x1234. A correct sequence of the WRITE commands will result in the WM72016 asserting an

interrupt by driving the DSPI CS high. Upon detection of a high state on the CS signal, the host

microcontroller drives two clock cycles on the DSPI CLK to acknowledge and clear the WM72016 interrupt.

The host microcontroller now has full and uninhibited access to the WM72016 memory. Any attempted access

by a RFID interrogator during this period will be disregarded until one of two conditions has occurred:

 The host microcontroller has released control of the WM72016 memory by writing an instruction with

the INTEND opcode, or

 The WM72016 has been power-cycled.

The entire interrupt generation sequence is shown in Figure 22. Note that the values x1200 and x0034 shown

in Figure 22 are shown for illustration purposes only – any two values whose XOR operation results in a value

of x1234 will generate a DSPI interrupt. The host microcontroller releases its control of the WM72016

memory by writing an instruction with an INTEND opcode refer to Table 9. The contents of the DSPI write

data word payload that follows the instruction word are ignored but must be present to constitute a valid DSPI

command.

NOTE: Should the outcome of two write cycles to USER memory locations 0x004 and 0x005 result in a XOR

value that is not 0x1234, the interrupt mechanism will be disabled until the WM72016 has been power-cycled.

In this case, the two memory locations may be used as standard USER memory, however any future use of

these memory locations may potentially generate an unintended interrupt – as such, it is not recommended to

use these memory locations as part of the standard USER memory bank.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 22 of 32

CS

CLK

Gen2 Generated Interrupt

D1

D0

REQRN

RN

16

WRITE

WR

OK

REQRN

RN

16

WRITE

WR

OK

RN16=xPPPP WordPtr=0x004;

Data=

xPPPP XOR x1200 RN16=xQQQQ WordPtr=0x005;

Data=

xQQQQ XOR x0034

Gen2

Interrogator

TX

WM72016

Backscatter

Tx

WM72016 RFID Gen2 Interface

WM72016 DSPI Interface

CS asserted by WM72016

Figure 22. Gen2 Interrupt Generation

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 23 of 32

SPECIFICATIONS

WM72016‟s RFID Interface conforms to the Specification for RFID Air Interface EPC Class-1 Generation-2 UHF

RFID Protocol for Communications at 860 MHz – 960 MHz, Version 1.2.0.

Options and Exceptions are noted here:

State Persistence Requirements

WM72016 features infinite state retention for S1, S2, S3, and SL State flags. State flag S0 has no persistence

and will always return to state „A‟ upon a power cycle.

ELECTRICAL SPECIFICATIONS

ABSOLUTE MAXIMUM RATINGS

Symbol

Description

Ratings

Notes

VDDR,

VDDRAW

Power Supply Voltage with respect to ANT-

-1.0V to +4.5V

VIN

Voltage on any serial port pin with respect to ANT-

-1.0V to +4.5V

and VIN < VDD+1.0V

TSTG

Storage Temperature

-55C to + 125C

TOP

Operating Temperature

-40oC to +85oC

TLEAD

Lead Temperature (Soldering, 10 seconds)

260 C

VESD

(ANT+, ANT-)

Electrostatic Discharge Voltage

- Human Body Model (JEDEC Std JESD22-A114-B)

- Charged Device Model (JEDEC Std JESD22-C101-A)

- Machine Model (JEDEC Std JESD22-A115-A)

500V

1kV

50V

VESD

(All other pins)

Electrostatic Discharge Voltage

- Human Body Model (JEDEC Std JESD22-A114-B)

- Charged Device Model (JEDEC Std JESD22-C101-A)

- Machine Model (JEDEC Std JESD22-A115-A)

1.5kV

200V

ME

Memory Endurance: Read or Write or Erase

1x1014

1

RFexp

RF Exposure

+10dBm

(800 ~ 1000 MHz)

Package Moisture Sensitivity Level

MSL-2

1. A degradation in memory endurance may occur for VDDR_EXT levels beyond the maximum specification.

Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only, and

the functional operation of the device at these or any other conditions above those listed in the operational section of this specification is

not implied. Exposure to absolute maximum ratings conditions for extended periods may affect device reliability.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 24 of 32

RF Operating Characteristics (TA = -40 C to + 85 C unless otherwise specified)

Symbol

Parameter

Min

Typ

Max

Units

Notes

SR

Read Sensitivity

-6

dBm

SW

Write Sensitivity

-6

dBm

Fr

Max Sustainable Read Rate @ SR

640

Kbits/s

1

Fw

Max Sustainable Write Rate @ Sw

160

Kbits/s

1

tST

Power-on time

1.0

1.5

ms



Change in Modulator Reflection

Coefficient

TBD

ZIN

Input Impedance @ fIN=915MHz

63 – j199

Ohms

2

Note:

1. Actual read & write speeds are constrained by the EPC Class 1 Gen2 data communication standard.

2. ZIN is measured at SR/SW.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 25 of 32

DSPI SERIAL PORT TIMING

Ser_clk

INSTR_WORD DATA_WORD

Ser_d1

INSTR_WORD DATA_WORD

Ser_d0

Ser_cs

tPSU tPH

VDDR

Figure 23. DSPI Power Supply Timing

tWD tCSH

tHD tCLK

tSU

tCSD

d14 d12 d10 d8 d6 d4 d2 d0OP4 OP2 OP0 a8 a6 a4 a2 a0

d15 d13 d11 d9 d7 d5 d3 d1WR OP3 OP1 a9 a7 a5 a3 a1

CS

D0

D1

CLK

Figure 24. DSPI Write Cycle Detail

d14 d12 d10 d8 d6 d4 d2 d0OP4 OP2 OP0 a8 a6 a4 a2 a0

d15 d13 d11 d9 d7 d5 d3 d1RD OP3 OP1 a9 a7 a5 a3 a1

CS

D0

D1

CLK tDD

Figure 25. DSPI Read Cycle Detail

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 26 of 32

DSPI Serial Port DC Characteristics (TA = -40C to + 85C unless otherwise specified)

Symbol

Parameter

Min

Typ

Max

Units

Notes

VDDR,

VDDRAW

Power Supply Pins

2.1

2.5

3.0

V

1

IDD

Power Supply Operating Current

15

25

µA

VIL

Input Low Voltage

-0.3

0.3 VDDR

V

VIH

Input High Voltage

0.7 VDDR

VDDR+0.3

V

VOL

Output Low Voltage

-

0.3

V

VOH

Output High Voltage

VDDR - 0.3

-

V

NOTES:

1. Measured at the pin.

DSPI Serial Port AC Characteristics (TA = -40C to + 85C, VDD = 2.1V to 3.0V unless otherwise specified)

Symbol

Parameter

Min

Typ

Max

Units

Notes

tPSU

VDDR Setup Time

1.5

-

ms

tPH

VDDR Hold Time

0

-

ns

tCSD

Chip Select Setup to Data Valid Time

10

-

ns

tCSH

Chip Select Hold Time

10

-

ns

tSU

Data Setup Time

10

tCLK/2 - 10

ns

tHD

Data Hold Time

10

-

ns

tDD

Read Data Valid Time

600

ns

tCLK

Clock Period

1.6

-

µs

tWD

Instruction to Data Word Timing

tCLK/2

-

tACK

Interrupt Acknowledge Setup Time

10

-

ns

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 27 of 32

USER MEMORY BLOCK SIZE DEFINITION

x000

x001

x002

x003

x004

x005

x006

x007

x008

x009

x00A

x00B

x00C

x00D

x00E

x00F

x010

x011

BLK:0

BLK:1

BLK_SIZ=111

BLK:0

BLK_SIZ=110

BLK:0

BLK:1

BLK_SIZ=101

BLK:0

BLK:1

BLK_SIZ=100

BLK:0

BLK:1

BLK:2

...

BLK_SIZ=011

BLK:0

BLK:1

BLK:2

BLK:3

BLK:4

...

BLK_SIZ=010

BLK:0

BLK:1

BLK:2

BLK:3

BLK:4

BLK:5

BLK:6

BLK:7

BLK:8

...

BLK_SIZ=001

BLK:0

BLK:1

BLK:2

BLK:3

BLK:4

BLK:5

BLK:6

BLK:7

BLK:8

BLK:9

BLK:10

BLK:11

BLK:12

BLK:13

BLK:14

BLK:15

BLK:16

BLK:17

BLK_SIZ=000

...

USER

MEMORY

ADDRESS

x013

x012

x014

x017

x018

x01F

x020

x03F

x040

x07F

x080

x0FF

x100

...

BLK:1

...

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 28 of 32

CIRCUIT EXAMPLE

The WM72016 may be implemented in a manner similar to that shown below.

WM72016

CLK

D1

D0

CS

Vddr

ANT+

ANT-

VDDR_EXT

µP

GND

I/O

Bus termination

may be required

Vddraw

Matching

network

NOTES:

1. RF performance of WM72016 is heavily dependent on matching impedance on the antenna port ANT+/-.

2. External voltage VDDR_EXT may be applied to Vddraw to externally power the WM72016.

VDDR_EXT must comply with specifications given in the DC Characteristics of this datasheet.

3. In some cases, additional bus termination may be required on the WM72016 end of the DSPI serial bus.

This is dependent on a number of factors, including bus length, bus impedance, connectors, processor

drive voltage, I/O port drive strength, and I/O slew rate. Excessive ringing on the bus may generate

voltages beyond specifications causing unpredictable performance characteristics.

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 29 of 32

SPECIFICATION & COMPLIANCE SUMMARY

Refer to EPCTM Radio-Frequency Identity Protocols Class-1 Generation-2 UHF RFID Protocol for

Communications at 860MHz-960MHz Version 1.2.0 for all critical RFID specifications.

Link to specifications page:

http://www.epcglobalus.org/Standards/EPCglobalSpecifications/tabid/335/Default.aspx

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 30 of 32

MECHANICAL DRAWINGS

8-pin UDFN (3.0 mm x 3.0 mm body, 0.65 mm pad pitch)

Note: All dimensions in millimeters. Care must be taken to ensure PCB traces and vias are not

placed within the exposed metal pad area.

UDFN PACKAGE MARKING SCHEME FOR BODY SIZE 3mm X 3mm

Legend:

XXXXXXX= base part number (WM72016)

LLLLLLLL= lot code

R=revision, P=package (D=DFN), N=split designator (numeric)

RIC=Ramtron Int‟l Corp, YY=year, WW=work week

Example: WM72016, “Green” UDFN-8 package, Lot 0411702,

Rev B., Year 2010, Work Week 12

WM72016

0411702

BD1

RIC1012

XXXXXXXX

LLLLLLLL

RPN

RICYYWW

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 31 of 32

ORDERING INFORMATION

Note: Contact Ramtron for other ordering options, i.e. bumped die.

Product

Description

Delivery & MOQ

WM72016-6-DGTR

8-pin UDFN with 16Kb memory and DSPI serial interface

Tape & Reel – 3000 units

WM72016 – Secure F-RAM with Gen-2 RFID and Serial Port

Rev. 1.4

May 2011 Page 32 of 32

REVISION HISTORY

Revision

Date

Summary

0.1

12/12/2008

Initial release.

0.2

2/11/2009

Order information and package update

0.3

3/7/2010

Documentation updates

1.0

3/12/2010

Changed to Preliminary status.

1.1

8/23/2010

Changed read/write sensitivity specs.

1.2

9/7/2010

Changed input impedance and the test frequency.

1.3

4/11/2011

Documentation updates and clarifications.

1.4

5/25/2011

Modified Memory Map table on p. 5 (changed line entries for DSPI address

0x3FA – 0x3FB).