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DS1993L-F5 |DS1993LF5MAIXMN/a1500avai1kbit/4kbit Memory iButtonTM DS1994 4-kbit Plus Time Memory iButtonTM
DS1994L-F5 |DS1994LF5MAIXMN/a1500avai4kb plus time memory iButton


DS1993L-F5 ,1kbit/4kbit Memory iButtonTM DS1994 4-kbit Plus Time Memory iButtonTMFEATURESYYWW REGISTERED RR Unique, Factory-Lasered and Tested 64-bit06DD17.35Registration Num ..
DS1993L-F5+ ,iButton 1Kb/4Kb Memoryblock diagram (Figure 1) shows the parasite-powered circuitry. This circuitry steals power whenever ..
DS1994L-F5 ,4kb plus time memory iButtonblock diagram (Figure 1) shows the parasite-powered circuitry. This circuitry steals power whenever ..
DS1994L-F5+ ,iButton 4Kb Memory Plus TimeFEATURES  4096 bits of Read/Write Nonvolatile Memory  Unique, Factory-Lasered, and Tested 64-bit ..
DS1995L-F5 ,16-kbit Memory iButtonDS1995TM16-kbit Memory iButtonwww.dalsemi.com§ Meets UL#913 (4th Edit.); Intrinsically SafeSPECIAL
DS1995L-F5 ,16-kbit Memory iButtonFEATURESApparatus, approved under Entity Concept§ 16384 bits of read/write nonvolatile memoryfor us ..


DS1993L-F5-DS1994L-F5
1kbit/4kbit Memory iButtonTM DS1994 4-kbit Plus Time Memory iButtonTM
SPECIAL FEATURES4096 bits of Read/Write Nonvolatile
Memory (DS1993)1024 bits of Read/Write Nonvolatile
Memory (DS1992)256-bit Scratchpad Ensures Integrity of Data
TransferMemory Partitioned into 256-bit Pages for
Packetizing DataData Integrity Assured with StrictRead/Write ProtocolsOperating Temperature Range from -40°C to
+70°COver 10 years of data retention
COMMON iButton FEATURES
Unique, Factory-Lasered and Tested 64-bit
Registration Number (8-bit Family Code +
48-bit Serial Number + 8-bit CRC Tester)
Assures Absolute Traceability Because No
Two Parts are AlikeMultidrop Controller for MicroLANDigital Identification and Information by
Momentary ContactChip-Based Data Carrier Compactly Stores
InformationData Can be Accessed While Affixed to
ObjectEconomically Communicates to Bus Master
with a Single Digital Signal at 16.3kbpsStandard 16mm Diameter and 1-Wire®
Protocol Ensure Compatibility with iButton®
FamilyButton Shape is Self-Aligning with Cup-
Shaped ProbesDurable Stainless Steel Case Engraved with
Registration Number Withstands HarshEnvironmentsEasily Affixed with Self-Stick Adhesive
Backing, Latched by its Flange, or Locked
with a Ring Pressed onto its RimPresence Detector Acknowledges When
Reader First Applies VoltageMeets UL#913 (4th Edit.); Intrinsically Safe
Apparatus, Approved under Entity Concept
for use in Class I, Division 1, Group A, B, Cand D Locations
F5 MICROCAN

GND
© 1993
YYWW REGISTERED RR06
000000FBD804
All dimensions shown in millimeters.
ORDERING INFORMATION

DS1992L-F5 F5 MicroCan
DS1993L-F5 F5 MicroCan
EXAMPLES OF ACCESSORIES

DS9096P Self-Stick Adhesive Pad
DS9101 Multipurpose Clip
DS9093RA Mounting Lock RingDS9093F Snap-In Fob
DS9092 iButton Probe
DS1992/DS1993
1kb/4kb Memory iButton
DS1992/DS1993
iButton DESCRIPTION

The DS1992/DS1993 memory iButtons (hereafter referred to as DS199_) are rugged read/write data
carriers that act as a localized database, easily accessible with minimal hardware. The nonvolatile
memory and optional timekeeping capability offer a simple solution to storing and retrieving vital
information pertaining to the object to which the iButton is attached. Data is transferred serially through
the 1-Wire protocol that requires only a single data lead and a ground return.
The scratchpad is an additional page that acts as a buffer when writing to memory. Data is first written to
the scratchpad where it can be read back. After the data has been verified, a copy scratchpad command
transfers the data to memory. This process ensures data integrity when modifying the memory. A 48-bit
serial number is factory lasered into each DS199_ to provide a guaranteed unique identity that allows forabsolute traceability. The durable MicroCan package is highly resistant to environmental hazards such as
dirt, moisture, and shock. Its compact coin-shaped profile is self-aligning with mating receptacles,
allowing the DS199_ to be easily used by human operators. Accessories permit the DS199_ to be
mounted on almost any surface including plastic key fobs, photo–ID badges, and PC boards.
Applications include access control, work-in-progress tracking, electronic travelers, storage of calibration
constants, and debit tokens.
OPERATION

The DS199_ have three main data components: 1) 64-bit lasered ROM, 2) 256-bit scratchpad, and 3)
1024-bit (DS1992) or 4096-bit (DS1993) SRAM. All data is read and written least significant bit first.
The memory functions are not available until the ROM function protocol has been established. This
protocol is described in the ROM functions flow chart (Figure 9). The master must first provide one of
four ROM function commands: 1) read ROM, 2) match ROM, 3) search ROM, or 4) skip ROM. After a
ROM function sequence has been successfully executed, the memory functions are accessible and themaster can then provide any one of the four memory function commands (Figure 6).
PARASITE POWER

The block diagram (Figure 1) shows the parasite-powered circuitry. This circuitry steals power whenever
the data input is high. The data line provides sufficient power as long as the specified timing and voltage
requirements are met. The advantages of parasite power are two-fold: 1) by parasiting off this input,lithium is conserved, and 2) if the lithium is exhausted for any reason, the ROM can still be read
normally.
64-bit LASERED ROM

Each DS199_ contain a unique ROM code that is 64 bits long. The first 8 bits are a 1-Wire family code.
The next 48 bits are a unique serial number. The last 8 bits are a CRC of the first 56 bits. (See Figure 2.)
The 1-Wire CRC is generated using a polynomial generator consisting of a shift register and XOR gates
as shown in Figure 3. The polynomial is X8 + X5 + X4 + 1. Additional information about the Dallas 1-Wire
Cyclic Redundancy Check is available in the Book of DS19xx iButton Standards. The shift register bitsare initialized to zero. Then starting with the least significant bit of the family code, 1 bit at a time is
shifted in. After the 8th bit of the family code has been entered, then the serial number is entered. After
the 48th bit of the serial number has been entered, the shift register contains the CRC value. Shifting in
the 8 bits of CRC should return the shift register to all zeros.
DS1992/DS1993
Figure 1. DS199_ BLOCK DIAGRAM

SRAM
16 PAGES of 256-
BITs (1993)
256-BITSCRATCHPAD
1-W
PARASITE-
CIRCUITRYPOWERED
MEMORYFUNCTIONCONTROL
1-WIRE
PORT
3V LITHIUM
4 PAGES of 256-
BITs (1992)
Figure 2. 64-BIT LASERED ROM

MSBLSB
MSBLSBMSBLSBMSBLSB
Figure 3. 1-WIRE CRC CODE
DS1992/DS1993
Figure 4a. DS1993 MEMORY MAP

PAGE 0
PAGE
PAGE 1
PAGE 2
PAGE 3
PAGE 4
PAGE 5
PAGE 6
PAGE 7
PAGE 8
PAGE 9
PAGE 10
PAGE 11
PAGE 12
PAGE 13
PAGE 14
PAGE 15
SCRATCHPAD
MEMORY
0000h
0020h
0040h
0060h
0080h
00A0h
00C0h
00E0h
0100h
0120h
0140h
0160h
0180h
01A0h
01C0h
01E0h
NOTE: Each page is 32 bytes (256 bits). The hex valuesrepresent the starting address for each page or register.
Figure 4b. DS1992 MEMORY MAP

PAGE 0
PAGE
PAGE 1
PAGE 2
PAGE 3
SCRATCHPAD
MEMORY
0000h
0020h
0040h
0060h
NOTE: Each page is 32 bytes (256 bits). The hex values
represent the starting address for each page or register.
DS1992/DS1993
MEMORY

The memory map in Figure 4 shows a 32-Byte page called the scratchpad, and additional 32-Byte pages
called memory. The DS1992 contains pages 0 though 3 that make up the 1024-bit SRAM. The DS1993
contain pages 0 through 15 that make up the 4096-bit SRAM.
The scratchpad is an additional page that acts as a buffer when writing to memory. Data is first written tothe scratchpad where it can be read back. After the data has been verified, a copy scratchpad command
transfers the data to memory. This process ensures data integrity when modifying the memory.
MEMORY FUNCTION COMMANDS
The Memory Function Flow Chart (Figure 6) describes the protocols necessary for accessing the memory.
An example follows the flow chart. Three address registers are provided as shown in Figure 5. The first
two registers represent a 16-bit target address (TA1, TA2). The third register is the ending offset/data
status byte (E/S).
The target address points to a unique Byte location in memory. The first 5 bits of the target address
(T4:T0) represent the Byte offset within a page. This Byte offset points to one of 32 possible Byte
locations within a given page. For instance, 00000b points to the first Byte of a page where as 11111b
would point to the last Byte of a page.
The third register (E/S) is a read only register. The first 5 bits (E4: E0) of this register are called the
ending offset. The ending offset is a Byte offset within a page (1 of 32 Bytes). Bit 5 (PF) is the partial
Byte flag. Bit 6 (OF) is the overflow flag. Bit 7 (AA) is the authorization accepted flag.
Figure 5. ADDRESS REGISTERS

TARGET ADDRESS (TA1)
TARGET ADDRESS (TA2)
ENDING ADDRESS WITHDATA STATUS (E/S)
(READ ONLY)
Write Scratchpad Command [0Fh]

After issuing the write scratchpad command, the user must first provide the 2-Byte target address,
followed by the data to be written to the scratchpad. The data is written to the scratchpad starting at the
byte offset (T4:T0). The ending offset (E4:E0) is the Byte offset at which the host stops writing data. The
maximum ending offset is 11111b (31d). If the host attempts to write data past this maximum offset, the
overflow flag (OF) is set and the remaining data is ignored. If the user writes an incomplete Byte and anoverflow has not occurred, the partial Byte flag (PF) is set.
Read Scratchpad Command [AAh]

This command can be used to verify scratchpad data and target address. After issuing the read scratchpad
command, the user can begin reading. The first two Bytes are the target address. The next Byte is the
ending offset/data status Byte (E/S) followed by the scratchpad data beginning at the Byte offset (T4: T0).
DS1992/DS1993
Copy Scratchpad [55h]

This command is used to copy data from the scratchpad to memory. After issuing the copy scratchpad
command, the user must provide a 3-byte authorization pattern. This pattern must exactly match the data
contained in the three address registers (TA1, TA2, E/S, in that order). If the pattern matches, the AA
(Authorization Accepted) flag is set and the copy begins. A logic 0 is transmitted after the data has been
copied until the user issues a reset pulse. Any attempt to reset the part is ignored while the copy is in
progress. Copy typically takes 30�s.
The data to be copied is determined by the three address registers. The scratchpad data from the
beginning offset through the ending offset is copied to memory, starting at the target address. Anywherefrom 1 to 32 Bytes can be copied to memory with this command. Whole Bytes are copied even if only
partially written. The AA flag is cleared only by executing a write scratchpad command.
Read Memory [F0h]

The read memory command can be used to read the entire memory. After issuing the command, the user
must provide the 2-Byte target address. After the two Bytes, the user reads data beginning from the target
address and may continue until the end of memory, at which point logic 1’s are read. It is important torealize that the target address registers contains the address provided. The ending offset/data status Byte
is unaffected.
The hardware of the DS1992/DS1993 provides a means to accomplish error-free writing to the memory
section. To safeguard reading data in the 1-Wire environment and to simultaneously speed up datatransfers, it is recommended to packetize data into data packets of the size of one memory page each.
Such a packet would typically store a 16-bit CRC with each page of data to ensure rapid, error-free data
transfers that eliminate having to read a page multiple times to determine if the received data is correct or
not. (See Application Note 114 for the recommended file structure to be used with the 1-Wire
environment.)
DS1992/DS1993
Figure 6. MEMORY FUNCTIONS FLOW CHART

Master TX MemoryFunction Command
DS199X sets Scratchpad Offset = (T4:T0) and
Clears (PF, OF, AA)
DS199X sets (E4:E0)
= Scratchpad Offset
DS199X IncrementsScratchpad Offset
Bus Master TXTA1 (T7:T0)
Bus Master TXTA2 (T15:T8)
Master TX Data Byte
To Scratchpad Offset
Bus MasterTX Reset0FHWrite
ScratchpadBus MasterTX Data
PF = 1
Bus MasterTX Reset
To Figure 6
Second Part
Bus Master RXTA1 (T7:T0)
Bus Master RXTA2 (T15:T8)
Master RX Ending Offset with DataStatus (E/S)
DS199X SetsScratchpad Offset=(T4:T0)
Bus MasterTX ResetDS199X IncrementsScratchpad Offset
Master RX DataByte FromScratchpad OffsetScratch-pad Offset =11111b
Scratchpad
AAHRead
Bus MasterRX "1"s
OF = 1
Scratch-pad Offset =11111b
PartialByte Written
DS199X TXPresence Pulse(See Figure 9)
DS1992/DS1993
Figure 6. MEMORY FUNCTIONS FLOW CHART (Continued)

Bus Master TX
TA1 (T7:T0)
Bus Master TXTA2 (T15:T8)
Scratchpad
55HCopy
First Part
Bus Master TXE/S Byte
DS199X CopiesScratchpad DataTo Memory
Auth-
Code Match
DS199X TX "1"s
DS199X TX "0"s
AA = 1
F0HRead MemoryN
To Figure 6
First PartBus MasterTX Reset
Bus MasterTX ResetY
Bus Master TX
TA1 (T7:T0)
Bus Master TX
TA2 (T15:T8)
DS199X sets Memory
Address = (T15:T0)
Master RX Data Byte FromMemory Address
Bus MasterTX Reset
Memory
DS199X
Address CounterIncrements
Bus MasterRX "1"s
Address= 21Dh
rization
DS1992/DS1993
MEMORY FUNCTION EXAMPLES

Example: Write two data Bytes to memory locations 0026h and 0027h (the seventh and eighth Bytes of
page 1). Read entire memory.
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