Microchip MCP452WF 13.56 mhz read/write passive rfid device Datasheet

MCRF450/451/452/455
13.56 MHz Read/Write Passive RFID Device
Features
Applications
• Contactless read and write with anti-collision
algorithm
• 1024 bits (32 blocks) of total memory
• 928 bits (29 blocks) of user programmable
memory
• Unique 32-bit tag ID (factory programmed)
• 32 bits for data and 16 bits for CRC per block
• Block write protection
• 70 Kbit/s read data rate (Manchester format)
• Special bit (Fast Read) for fast identification and
anti-counterfeit applications (EAS)
• 1-of-16 PPM encoding for writing data
• Interrogator-Talks-First (ITF) or Tag-Talks-First
(TTF) operation
• Long range for reading and writing
• High-speed anti-collision algorithm for reading
and writing
• Fast and Normal modes for write data speed
• Anti-tearing feature for secure write transactions
• Asynchronous operation for low power
consumption and flexible choice of carrier
frequency bands
• Internal resonance capacitors
(MCRF451/452/ 455)
• Two pad connections for external antenna circuit
(MCRF452)
• Three pad connections for external antenna
circuit (MCRF450, 451, 455)
• Very low power CMOS design
• Die in waffle pack, wafer, wafer on frame, bumped
wafer, COB, PDIP or SOIC package options
• Item Level Tagging: To read and write multiple
items in long read range environment.
• Anti-Counterfeit: The device has a unique
feature to distinguish between paid, unpaid or
returned merchandise.
• Inventory Management: Tag’s data can be read
or updated (written) in multiple tags and long
range environment. Its memory (32 blocks, 1 Kbit,
each block = 32 bits) is well organized for the
inventory management applications.
• Product Identifications
• Airline Baggage Tracking
• Book Store and Library Book ID
• Low Cost Animal Ear Tags: The device’s long
range reading performance combined with 1 Kbit
of memory is suitable for animal tagging applications. Tag cost can be cheaper and read range is
much longer than existing 125 kHz conventional
animal ear tags.
• Toys and Gaming Tools: Device’s anti-collision
feature for reading and writing allows to make
intelligent interactive toys and gaming tools.
• Access Control and Time Attendance Cards:
Device’s long range performance allows to make
long range access control, parking lot entry, and
time attendance cards.
Inexpensive finished tags and readers are available
from Microchip’s worldwide OEM partners. Please
contact Microchip Technology Inc. near you or visit
http://www.microchip.com
for
further
product
information and inquiries for your applications.
Typical Configuration for Applications
Read/Write
Command and Data
Interrogator
(Reader/Writer)
Ant. A
MCRF452
Data
VSS
Read/Write Range:~ up to 1.5 meters depending
on tag size and system
requirements.
 2003 Microchip Technology Inc.
DS40232H-page 1
MCRF450/451/452/455
Package Types
PDIP (“P”)
ANT. A
1
8
VDD
NC
2
7
FCLK
ANT. B
3
6
NC
CLK
4
5
VSS
Note: Pins 4, 7 and 8 are for device test purposes only
NC = Not Connected
MCRF450/451/455: Antenna connections = pins 1, 3 and 5
MCRF452: Antenna connections = pins 1 and 5
ROTATED SOIC (“X/SN”)
ANT.B
1
8
ANT. A
NC
2
7
VDD
CLK
3
6
NC
VSS
4
5
FCLK
Note: Pins 3, 5 and 7 are for device test purposes only
NC = Not Connected
MCRF450/451/455: Antenna connections = pins 1, 4 and 8
MCRF452: Antenna connections = pins 4 and 8
MCRF450 COB (“7M”)
8 mm
Antenna Coil Connection
5 mm
Thickness = 0.4 mm
DS40232H-page 2
 2003 Microchip Technology Inc.
MCRF450/451/452/455
1.0
DESCRIPTION OF DEVICE
FEATURES
The MCRF450/451/452/455 is a contactless read/write
passive RFID device that is optimized for 13.56 MHz
RF carrier signal. The device needs an external LC
resonant circuit to communicate wirelessly with the
Interrogator. The device is powered remotely by
rectifying an RF signal that is transmitted from the
Interrogator and transmits or updates its contents from
memory-based on commands from the Interrogator.
The device is engineered to be used effectively for item
level tagging applications, such as retail and inventory
management, where a large volume of tags are read
and written in the same Interrogator field.
The device contains 32 blocks (B0-B31) of EEPROM
memory. Each block consists of 32 bits. The first three
blocks (B0-B2) are allocated for device operation, while
the remaining 29 blocks (B3-B31: 928 bits) are for user
data. Block 1 contains unique 32 bits of Tag ID. The Tag
ID is preprogrammed at the factory and write protected.
All blocks, except for the Tag ID (Block 1), are contactlessly writable block-wise by Interrogator commands.
All data blocks, with the exception of bits 30 and 31 in
Block 0, are write-protectable.
The device can be configured as either Tag-Talks-First
(TTF) or Interrogator-Talks-First (ITF). In TTF mode,
the device transmits its fast response data (160 bits
max., see Example 9-1) as soon as it is energized, then
waits for the next command. In ITF mode, the device
requires an Interrogator command before it sends any
data. The control bits for TTF and ITF modes are bits
30 and 31 in Block 0.
All downlink commands from the Interrogator are
encoded using 1-of-16 Pulse Position Modulation
(PPM) and specially timed gap pulses. This encoded
information amplitude modulates the Interrogator’s RF
carrier signal.
At the other end, the MCRF450/451/452/455 device
demodulates the received RF signal and then sends
data (from memory) at 70 Kbit/s back to the Interrogator
in Manchester format.
The communication between Interrogator and device
takes place asynchronously. Therefore, to enhance the
detection accuracy of the device, the Interrogator
sends a time reference signal (time calibration pulse) to
the device, followed by the command and programming data. The time reference signal is used to
calibrate timing of the internal decoder of the device.
There are device options for the internal resonant
capacitor between antenna A and VSS: (a) no internal
resonant capacitor for the MCRF450, (b) 100 pF for the
MCRF451, (c) two 50 pF in series (25 pF in total) for
the MCRF452 and (d) 50 pF for the MCRF455. The
internal resonant capacitors for each device are shown
in Figures 2-2 through 2-5.
 2003 Microchip Technology Inc.
The MCRF450 needs an external LC resonant circuit
connected between antenna A, antenna B and VSS
pads. See Figure 2-2 for the external circuit configuration. The MCRF452 needs a single external antenna
coil only between antenna A and VSS pads, as shown
in Figure 2-4.
This external circuit, along with the internal resonant
capacitor, must be tuned to the carrier frequency of the
Interrogator for maximum performance.
When a tag (device with the external LC resonant
circuit) is brought to the Interrogator’s RF field, it
develops an RF voltage across the external circuit. The
device rectifies the RF voltage and develops a DC
voltage (VDD). The device becomes functional as soon
as VDD reaches the operating voltage level.
The device then sends data stored in memory to the
Interrogator by turning on/off the internal modulation
transistor. This internal modulation transistor is located
between antenna B and VSS. The modulation transistor
has a very small turn-on resistance between Drain
(antenna B) and Source (VSS) terminals during its turn-on
time.
When the modulation transistor turns on, the resonant
circuit component between antenna B and VSS, which
is in parallel with the modulation transistor, is shorted
due to the low turn-on resistance. This results in a
change in the LC value of the circuit. As a result, the
circuit no longer resonates at the carrier frequency of
the Interrogator. Therefore, the voltage across the
circuit is minimized. This condition is called “cloaking”.
When the modulation transistor turns off, the circuit
resonates at the carrier frequency of the Interrogator
and develops maximum voltage. This condition is
called “uncloaking”. Therefore, the data is sent to the
Interrogator by turning on (cloaking) and off
(uncloaking) the modulation transistor.
The voltage amplitude of the carrier signal across the
LC resonant circuit changes depending on the
amplitude of modulation data. This is called an amplitude modulation signal. The receiver channel in the
Interrogator detects this amplitude modulation signal
and reconstructs the modulation data for decoding.
The device includes a unique anti-collision algorithm to
be read or written effectively in multiple tag environments. To minimize data collision, the algorithm utilizes
time division multiplexing of the device response. Each
device can communicate with the Interrogator in a
different time slot. The devices in the Interrogator’s RF
field remain in a nonmodulating condition if they are not
in the given time slot. This enables the Interrogator to
communicate with the multiple devices one at a time
without data collision. The details of the algorithm are
described in Section 6.0 “Read/Write Anti-Collision
Logic”.
DS40232H-page 3
MCRF450/451/452/455
To enhance data integrity for writing, the device
includes an anti-tearing feature. This anti-tearing
feature provides verification of data integrity for
incomplete write cycles due to failed communication
between the Interrogator and the device during the
write sequences.
Based upon the FRR response, the Interrogator will
send Matching Code 1 (MC1) or Matching Code 2
(MC2) during the tag’s listening window. The Interrogator sends the MC1 to put the tag into Sleep mode. Tags
in Sleep mode never respond to any command.
Removal of the Interrogator’s RF energy from the
device is the only way to wake-up the device.
1.1
If the tag needs further read/write processing, the
Interrogator sends the MC2, followed by a Read or
Write command. After the completion of reading or
writing of block data, the Interrogator sends an End
command to put the tag into Sleep mode.
Device’s Communication with
Interrogator
The device can be operated in either Fast Read
Request (FRR) or Fast Read Bypass (FRB) mode,
depending on the status of bit 31 (FR: bit) of Block 0. If
the FR bit is set, the device is operated in FRR mode,
and FRB mode, if the FR bit is cleared. The FR bit is
always reprogrammable and not write-protectable. The
FRR mode is a default setting. The communication
between the Interrogator and tag starts with a FRR or
FRB command.
In FRR mode, the device sends a response only when
it receives the FRR command, not the FRB command.
Conversely, the device in FRB mode sends a response
when it receives the FRB command only, not the FRR
command.
If the device is set to FRR mode and also set to TTF
mode (TF bit = set), the device can send the FRR
response as soon as it is energized.
One of the main purposes of using the two different
modes (FRR and FRB) is to use the device effectively
in the item level supply-chain application, where a rapid
identification and an effective anti-collision read/write
process is needed (i.e., to identify whether it is a paid
or unpaid item, or whether it passed one particular point
of interest or not). This can be done by either checking
the status of the FR bit or by checking the response of
the tag to the command. For this reason, the FR bit is
also called an Electronic Article Surveillance (EAS) bit.
1.1.1
OPERATION OF TAG IN FRR MODE
If the device is in the FRR mode (FR bit = set), the
communication between the Interrogator and the
device can start in two ways, depending on the status
of TF (Bit 30 of Block 0). If the TF bit is cleared, it is
called ITF mode. In this case, the tag waits for the
Interrogator’s FRR command and sends the FRR
response data when it sees the FRR command. If the
TF bit is set, the device is in a TTF mode. In this case,
the tag sends the FRR response as soon as it is
energized, even without the FRR command. The tag
has a short listening window (1 ms) immediately after
the FRR response. The Interrogator sends its next
command during this listening window.
The reading and writing of the FRR devices takes place
in the Anti-collision mode. For instance, if there are
multiple tags in the field, the Interrogator selects one
tag at a time by controlling the tag’s time slot for the
FRR response. The Interrogator repeats this sequence
until all tags in its field are processed:
- send FRR command
- receive FRR response
- send Matching Code 1 or 2 at tag’s listing
window
- send Read Block command/or send Write
Block command and data
- verify read/write response
- send End command
- verify the End command response
- look for other tag’s FRR responses
1.1.2
OPERATION OF TAG IN FRB MODE
The communication with the device in the FRB mode is
initiated by the FRB command only. If the device sees
the Interrogator’s FRB command, it sends its 32-bit tag
ID and waits for the MC2. This is followed by a Read or
Write command. Once the device is read or written, the
Interrogator sends an End command. Unlike the FRR
mode, the reading and writing of the tag are processed
in a non Anti-collision mode.
See Section 6.0 “Read/Write Anti-Collision Logic”,
for the read and write anti-collision algorithm. See
Example 9-1 for command sequences and device
responses.
The FRR response includes the 32 bits of tag ID and
FRF (Blocks 3 -5). See Tables 7-3, 7-4 and 7-6 for
data. The Interrogator identifies which tags are in the
field by receiving their FRR responses.
DS40232H-page 4
 2003 Microchip Technology Inc.
MCRF450/451/452/455
2.0
ELECTRICAL CHARACTERISTICS
TABLE 2-1:
ABSOLUTE RATINGS
Parameters
Symbol
Min
Max
Units
Conditions
IPP_AC
—
40
mA
Peak-to-Peak coil current
Coil current into coil pad
Maximum power dissipation
PMPD
—
0.5
W
—
Ambient temperature with power applied
TAMB
-40
+125
°C
—
TASM
—
300
°C
< 10 sec.
TSTORE
-65
150
°C
—
Assembly temperature
Storage temperature
Note:
Stresses above those listed under “Maximum ratings” may cause permanent damage to the device. This
is a stress rating only and functional operation of the device at those or any other conditions above those
indicated in the operational listings of this specification is not implied. Exposure to maximum rating
conditions for extended periods may affect device reliability.
TABLE 2-2:
OPERATING DC CHARACTERISTICS
Standard Operating Conditions (unless otherwise stated)
Operating Temperature = -20°C to +70°C
Parameters
Symbol
Min
Typ
Max
Units
Conditions
VDDR
2.8
—
—
V
VDD voltage for reading at 25°C
Operating current in
Normal mode
IOPER_N
—
20
—
µA
VDD = 2.8V during reading at 25°C
Operating current in
Fast mode
IOPER_F
—
45
—
µA
VDD = 2.8V during reading at 25°C
Reading voltage
Writing current
IWRITE
—
130
—
µA
At 25°C, VDD = 2.8V
Writing voltage
VWRITE
2.8
—
—
VDC
At 25 °C
Modulation resistance
RM
—
3.0
5.0
Ω
Data retention
—
200
—
—
Years
For T < 120°C
Endurance
—
1.0
—
—
Million
Cycles
At 25°C
 2003 Microchip Technology Inc.
DC turn-on resistance between
Drain and Source terminals of the
modulation transistor at VDD = 2.8V
DS40232H-page 5
MCRF450/451/452/455
TABLE 2-3:
OPERATING AC CHARACTERISTICS
Standard Operating Conditions (unless otherwise stated)
Operating Temperature = -20°C to +70°C.
Parameters
Symbol
Min
Typ
Carrier frequency
FC
2.0
13.56
35
MHz
Device data rate
FM
58
70
82
kHz
Pulse width of 1-of-16 PPM
for Normal mode
PWPPM_N
145
175
205
µs
See Figure 6-2 and Table 6-7,
175 µs ±17%
Pulse width of 1-of-16 PPM
for Fast mode
PWPPM_F
8.3
10
11.7
µs
See Figure 6-2 and Table 6-7
Symbol duration of 1-of16 PPM for Normal mode
SWPPM_N
2.32
2.8
3.28
ms
See Figure 6-9
Symbol duration of
1-of-16 PPM for Fast mode
SWPPM_F
133
160
187
µs
MODINDEX_GAP
20
60
100
%
See Figure 6-2
Gap width of Interrogator
command and data except
Fast mode data
GAPWIDTH_N
20
100
150
µs
See Figure 6-2 and Table 6-7
Gap width of Fast mode
data
GAPWIDTH_F
6.0
7.0
8.0
µs
See Figure 6-2 and Table 6-7
Coil voltage during reading
VPP_AC
4.0
—
—
VPP
Peak-to-Peak voltage across the coil
during reading
Detuning voltage
VDETUNE
3.0
4.0
—
VDC
VDD voltage at which the input voltage
limiting circuit becomes active
TWRITE
—
5.0
—
ms
Write time for a 32-bit block
TDECODE
0.97
1.225
1.48
ms
Time delay between end of command
symbol and start of the device
response
TSLOT
2.1
2.5
2.93
ms
TLW
0.82
1.0
1.17
ms
1.305 1.575 1.845
ms
175 µs/pulse position x 9 pulse
positions = 1.575 ms
CRES_100
85.5
95
104.5
pF
Between Ant. A and VSS pads at
13.56 MHz and at 25°C (MCRF451)
See Figure 2-3
CRES_2_50
27
30
33
pF
Between Ant. A and VSS pads at
13.56 MHz and at 25°C (MCRF452)
See Figure 2-4
CRES_50
45
50
55
pF
Between Ant. A and VSS pads at
13.56 MHz and at 25°C (MCRF455)
See Figure 2-5
CPARA_IN
—
3.5
—
pF
Between antenna pad A and VSS, at
13.56 MHz with modulation transistor
off (no external coils). Not tested in
production
Modulation index of gap
pulse
EEPROM (Memory)
Writing Time
Command Decode Time
Time slot
Listening Window
Command Duration of Fast
Read command (FRR and
FRB)
Internal Resonant
Capacitor
Parasitic Input Capacitance
of MCRF450
Note 1:
T_CMD_FRR
Max Units
Conditions
Manchester coding, both Normal and
Fast modes, 70 kHz ±17% (Note 1)
Tested in production at VDD = 2.8 VDC and 5.0 VDC.
DS40232H-page 6
 2003 Microchip Technology Inc.
MCRF450/451/452/455
TABLE 2-4:
PAD COORDINATES (MICRONS)
Lower
Upper
Passivation Openings
Pad Name
Left X
Left Y
Right X
Right Y
Pad Width
Pad Height
Pad
Center X
Pad
Center Y
Ant. Pad A
-853.50
-992.10
-764.50
-903.10
89.00
89.00
-809.00
-947.60
Ant. Pad B
759.50
-993.70
848.50
-904.70
89.00
89.00
804.00
-949.20
VSS
769.10
977.90
858.10
1066.90
89.00
89.00
813.60
1022.40
VDD
-839.50
45.50
-750.50
134.50
89.00
89.00
-795.00
90.00
CLK
721.10
77.80
810.10
166.80
89.00
89.00
765.60
122.30
FCLK
-821.50
910.70
-732.50
999.70
89.00
89.00
-777.00
955.20
Note 1:
All coordinates are referenced from the center of the die.
TABLE 2-5:
DIE MECHANICAL DIMENSIONS
Specifications
Min
Typ
Max
Unit
—
—
3.5 x 3.5
89 x 89
—
—
mil
µm
Note 1, Note 2
7.5
190.5
8
203.2
8.5
215.9
mil
µm
Sawed 8” wafer on frame
(option = WF) (Note 3)
10
11
12
mil
254
279.4
304.8
µm
• Bumped, sawed 8” wafer
on frame (option = WFB)
• Unsawed wafer (option = W)
• Unsawed 8” bumped
wafer (option = WB), (Note 3)
Die passivation thickness (multilayer)
—
1.3
—
µm
Note 4
Die Size:
Die size X*Y before saw (step size)
Die size X*Y after saw
—
—
1904 x 2340.8
1840.5 x 2277.3
—
—
µm
µm
—
—
Bond pad opening
Die backgrind thickness
Note 1:
2:
3:
4:
5:
Comments
The bond pad size is that of the passivation opening. The metal overlaps the bond pad passivation by at
least 0.1 mil.
Metal Pad Composition is 98.5% Aluminum with 1% Si and 0.5% Cu.
As the die thickness decreases, susceptibility to cracking increases. It is recommended that the die be as
thick as the application will allow.
The Die Passivation Thickness (1.3 µm) can vary by device depending on the mask set used. The
passivation is formed by:
- Layer 1: Oxide (undoped oxide)
- Layer 2: PSG (doped oxide)
- Layer 3: Oxynitride (top layer)
The conversion rate is 25.4 µm/mil.
Notice: Extreme care is urged in the handling and assembly of die products since they are susceptible to
mechanical and electrostatic damage.
TABLE 2-6:
WAFER MECHANICAL SPECIFICATIONS
Specifications
Min
Typ
Max
Unit
Wafer Diameter
—
8
—
inch
Die separation line width
—
80
—
µm
Dice per wafer
—
6,600
—
die
Batch size
—
24
—
wafer
 2003 Microchip Technology Inc.
Comments
DS40232H-page 7
MCRF450/451/452/455
FIGURE 2-1:
MCRF450/451/452/455 DIE LAYOUT
Top View
Y
(Notch edge of wafer)
1590.6
Vss
FCLK
900.1
865.2
CLK
VDD
X
1037.6
1071.5
Ant. A
Ant. B
1613
Note:
Die size before saw:
1904.0 µm x 2340.8 µm
1.904 mm x 2.3408 mm
74.96 mil x 92.16 mil
Coordinate units are in µm.
See Table 2-5 for die mechanical dimensions.
Die size after saw:
1840.5 µm x 2277.3 µm
1.8405 mm x 2.2773 mm
72.46 mil x 89.66 mil
Bond pad size:
89 µm x 89 µm
0.089 mm x 0.089 mm
3.5 mil x 3.5 mil
Bumped die:
Bumped Pad: Four corner pads (FCLK, VSS, Antenna B, Antenna A)
Bumping Material: 99.6% Gold
Bump Height: 25 µm ±3 µm
Bump Size: 103 µm x 103 µm (Covered all passivation opening of bond pad)
Other area except the four bumped pads: Covered by Polyamide
Thickness of Polyamide: 3 µm
DS40232H-page 8
 2003 Microchip Technology Inc.
MCRF450/451/452/455
TABLE 2-7:
PAD FUNCTION TABLE
Name
Function
Ant. Pad A Connected to antenna coil L1.
Ant. Pad B Connected to antenna coils L1 and L2
for MCRF450/451/455, NC for
MCRF452.
VSS
Connected to antenna coil L2.
Device ground during Test mode.
(VSS = substrate)
FCLK
For device test only. Leave floating or
connect to VSS in applications.
CLK
VDD
Note:
For device test only. Leave floating in
applications.
NC = Not Connected.
FIGURE 2-2:
EXTERNAL CIRCUIT CONFIGURATION FOR MCRF450
(a) Two inductors and one capacitor
1
f tuned = ---------------------2π L T C
Ant. A
1
f detuned = ---------------------2π L 1 C
LT = Total antenna inductance between Ant. A and VSS
L T = L 1 + L 2 + 2L M
Where: LM = mutual inductance of L1 and L2
MCRF450
L1
C
VSS
L2
L1 > L2
LM = K L1 L2
Ant. B
K = coupling coefficient of two inductors (0 ≤ K ≤ 1)
Note: Substrate = VSS
(b) One inductor and two capacitors
Ant. A
1
f tuned = -------------------------2π L T C T
C1
MCRF450
L
VSS
C2
C1 ≥ C2
1
f detuned = ---------------------2π LC 1
C1 C2
C T = -------------------C1 + C2
Ant. B
Note: Substrate = VSS
Note:
Input parasitic capacitance between Antenna A and VSS pads = 3.5 pF.
See application notes, AN710 and AN830 for antenna circuit design.
 2003 Microchip Technology Inc.
DS40232H-page 9
MCRF450/451/452/455
FIGURE 2-3:
EXTERNAL CIRCUIT CONFIGURATION FOR MCRF451
Ant. A MCRF451
Internal Resonant Capacitor (Cres_100) = 95 pF
Int. Res. Cap.
= 95 pF
L1
VSS
L2
Ant. B
L1 > L2
Note: Substrate = VSS
FIGURE 2-4:
Ant. A
L1:
External Antenna Coil A
L2:
External Antenna Coil B
1
f tuned = -----------------------------------------------– 12
2π ( L T )95 ×10
1
f detuned = ----------------------------------------------– 12
2π ( L 1 )95 ×10
LT = Total antenna inductance between Ant. A and VSS
EXTERNAL CIRCUIT CONFIGURATION FOR MCRF452
MCRF452
Internal Resonant Capacitor between Ant. A and VSS pads:
CRES_2_50 + parasitic capacitor = 30 pF
50.6 pF
Int. Res. Cap.
= 30 pF
L
65.4 pF
VSS
Ant. B
1
f tuned = ------------------------------------------– 12
2π ( L )30 ×10
1
f detuned = -----------------------------------------------– 12
2π ( L )50.6 ×10
Note: Substrate = VSS
FIGURE 2-5:
Ant. A
EXTERNAL CIRCUIT CONFIGURATION FOR MCRF455
MCRF455
Internal Resonant Capacitor (Cres_50) = 50 pF
1
f tuned = -----------------------------------------------– 12
2π ( L T )50 ×10
Int. Res. Cap.
= 50 pF
L1
1
f detuned = ----------------------------------------------– 12
2π ( L 1 )50 ×10
LT = Total antenna inductance between Ant. A and VSS
VSS
L2
Ant. B
L1 > L2 Note: Substrate = VSS
L1: External Antenna Coil A
L2: External Antenna Coil B
Note:
See application notes AN710 and AN830 for antenna circuit design of
Figure 2-2 through Figure 2-5.
DS40232H-page 10
 2003 Microchip Technology Inc.
MCRF450/451/452/455
TABLE 2-8:
INTERNAL RESONANT CAPACITANCE AND ANTENNA INDUCTANCE
REQUIREMENTS
External
Inductance
Connection to External
Requirement
Antenna Circuit
between Antenna
A and VSS for
13.56 MHz tag
Device
Name
Resonant
Capacitance
(Antenna A to
VSS)
MCRF451
95 pF ±10%
1.45 µH ±10%
MCRF452
30 pF ±10%
4.591 µH ±10%
MCRF455
50 pF ±10%
2.76 µH ±10%
Note:
Antenna A, B, and
VSS pads
Reference
This device requires three
connections to an external circuit.
Good for direct die attachment onto
antenna.
Antenna A and VSS pads This device requires only two
antenna connections. Good for both
direct die attachment and COB.
Antenna A, B, and
VSS pads
This device requires three
connections to an external circuit.
Good for direct die attachment onto
antenna.
The internal capacitance value for bumped die is about 1 pF higher than the unbumped die’s capacitor.
 2003 Microchip Technology Inc.
DS40232H-page 11
MCRF450/451/452/455
3.0
BLOCK DIAGRAM
The device contains four major sections. They are:
Analog Front-End, Detection/Encoding, Read/Write
Anti-collision Logic and Memory sections. Figure 3-1
shows the block diagram of the device.
FIGURE 3-1:
BLOCK DIAGRAM
DETECTION/ENCODING
SECTION
ANALOG FRONT-END SECTION
External Antenna Circuit
High/Low Voltage
Regulator
VDD
Demodulator (Detector)
To Memory
(High Voltage)
Fast Mode
Oscillator
Detuning Circuit
PPM
Decoder
Clock Generator
High Voltage (HV)
From
High Voltage
Regulator
Memory Array
Command
Decoder
VDD
Power-on Reset
(POR)
MEMORY SECTION
Registers
CRC/Parity Generator and Checker
To Anti-collision
Command Controller
(VDD)
Data Encoder
Main Clock
Modulation
READ/WRITE Anti-collision SECTION
VDD from POR
Anti-collision Command Controller
Time Slot
Counter
DS40232H-page 12
Time Slot Generator
(TC, TSMAX, Tag ID)
 2003 Microchip Technology Inc.
MCRF450/451/452/455
FIGURE 3-2:
DATA WAVEFORM OF DEVICE
DESCRIPTION
WAVEFORM
SIGNAL
Data
1
0
CLK
NRZ - L
(Reference only)
BIPHASE - L
(Manchester)
 2003 Microchip Technology Inc.
1
1 0
0
0
1
1
0
1
0
Digital Data
Internal Clock Signal
Non Return to Zero - Level
“1” is represented by logic high level.
“0” is represented by logic low level.
Biphase - Level (Split Phase)
A level change occurs at middle of
every bit clock period.
“1” is represented by a high to low
level change at midclock.
“0” is represented by a low to high
level change at midclock.
DS40232H-page 13
MCRF450/451/452/455
4.0
ANALOG FRONT-END
This section includes high and low voltage regulators,
Power-on Reset, 70 kHz clock generator and
modulation circuits.
4.1
High and Low Voltage Regulator
The high voltage circuit generates the programming
voltage for the memory section. The low voltage circuit
generates DC voltage (VDD) to operate the device.
4.2
4.5
Detuning Circuit
The purpose of this circuit is to prevent excessive RF
voltage across the resonant circuit.
This circuit monitors VDD and detunes the resonant
circuit if the RF coil voltage exceeds the threshold limit
(VDETUNE), which is above the operating voltage of the
device.
Power-On Reset (POR)
This circuit generates a Power-on Reset (POR)
voltage. The POR releases when sufficient power has
been developed by the voltage regulator to allow for
correct operation.
4.3
Clock Generator
This circuit generates a clock (CLK). The main clock is
generated by an on-board 70 kHz time base oscillator.
This clock is used for all timing in the device, except for
the Fast mode PPM decoding.
4.4
Data Modulation
The data modulation circuit consists of a modulation
transistor and a LC resonant circuit. The resonant
circuit must be tuned to the carrier frequency of the
Interrogator
(i.e.,
13.56 MHz)
for
maximum
performance.
The modulation transistor is placed between antenna B
and VSS pads. It is designed to result in the turn-on
resistance of less than five ohms (RM). This small turnon resistance shorts the resonant circuit component
between antenna B and VSS pads as it turns on. This
results in a change of the resonant frequency of the
resonant circuit. Consequently, the resonant circuit
becomes detuned with respect to the carrier frequency
of the Interrogator. The voltage across the resonant
circuit is minimized during this time. This condition is
called “cloaking”.
The transistor, however, releases the resonant circuit
as it turns off. Therefore, the resonant circuit tunes to
the carrier frequency of the Interrogator again and
develops maximum voltage. This condition is called
“uncloaking”.
The device transmits data by cloaking and uncloaking,
based on the on/off condition of the modulation transistor. Using the 70 kHz Manchester format, the data bit
‘0’ will be sent by cloaking and uncloaking the device
for 7 µs each. Similarly, the data bit ‘1’ will be sent by
uncloaking and cloaking the device for 7 µs each. See
Figure 6-1 for the Manchester waveform.
DS40232H-page 14
 2003 Microchip Technology Inc.
MCRF450/451/452/455
5.0
DETECTION AND ENCODING
2.
This section encodes data with the Manchester format
and also detects commands from the Interrogator.
5.1
Demodulator (Detector)
This circuit demodulates the Interrogator commands
and sends them to the PPM decoder.
5.2
Fast Mode Oscillator
This oscillator generates a clock frequency that is used
for decoding Fast mode commands.
5.3
PPM Signal Decoder
3.
This section decodes the PPM signals and sends the
results to the command decoder and CRC/parity
checker.
5.4
Command Decoder
This section decodes the Interrogator commands and
sends the results to the Anti-collision/command
controller.
5.5
5.6
CRC for Blocks 0 and 2: When reading Block
0 or 2, a Calculated CRC (CCRC) is sent. This
is because both the TF and FR bits in Block 0
are non write-protectable, while the rest of the
bits in the block are write-protectable. This
means the SCRC in the block no longer represents the CRC of the block data, if only the TF or
the FR bit is reprogrammed. This is also true for
Block 2, which is a write protection block. The
write-protected bit cannot be reprogrammed
once it has been written. Therefore, the SCRC in
Blocks 0 and 2 are not used. Instead, the device
calculates the current CRC of the block and
sends it to the Interrogator.
CRC for FRR response: For the Fast Read (FR)
response (this is the device response to an FRR
command), the CCRC of the tag ID and FRF
(Blocks 3-5) data is sent. The data length of the
FRF is determined by DF bits (see Table 7-6).
Data Encoder
This section multiplexes serial data, encodes it into
Manchester format and sends it to the modulation
circuit. See Figure 3-2 for the Manchester waveform.
CRC/Parity Generator and
Checker
This section generates Cyclic Redundancy Code
(CRC) and parity bits for transmitting and receiving
data. The device utilizes a 16-bit CRC for error
detection. Its polynomial and initial values are:
CRC Polynomial: X16+X12+X5+X0
Initial Value: $FFFF
This polynomial is also known as CRC CCITT
(Consultative Committee for International Telegraph
and Telephone). The Interrogator also uses the same
CRC for data processing. The device uses the CRC in
the following ways:
1.
CRC for blocks (except Blocks 0 and 2): The
Interrogator will send a Write command with
CRC. When the device receives this command,
it checks the CRC prior to any processing. If it is
a correct CRC, the device programs the block
data and also stores the CRC in the EEPROM.
As soon as the data is written into memory, both
the programmed data and Stored CRC (SCRC)
are sent back to the Interrogator as verification.
The device also sends the programmed data
and SCRC when there is a response to the
Read command.
If the CRC is incorrect, the device ignores the
incoming message (does not respond to the
Interrogator) and waits for the next command
with a correct CRC.
 2003 Microchip Technology Inc.
DS40232H-page 15
MCRF450/451/452/455
6.0
READ/WRITE ANTI-COLLISION
LOGIC
4.
This section includes the anti-collision algorithm of the
device and consists of the Anti-collision/command
controller, the time slot generator and the time slot
counter.
6.1
Figure 6-1 shows the anti-collision algorithm flowchart,
which consists of four control loops. They are:
Detection, Processing, Sleeping and Reactivation
loops. All devices in the Interrogator’s RF field are
controlled by five different commands and internal
control flags.
The Interrogator commands are:
1.
2.
3.
The MC1 and MC2 matching code command
consists of 12 bits or 3 symbols. The first 8 bits,
or the first two symbols, are selected from the
32-bit Tag ID. The next 4 bits, or the 3rd symbol,
determine the matching code type (3 bits) and a
parity bit (see Section 6.2.3.6 “Calculation Of
Matching Code”). The command lasts for
about 11.2 ms, including the TCP.
Description of Algorithm
The read/write anti-collision algorithm is based on time
division multiplexing of tag responses. Each device is
allowed to communicate with the Interrogator in its time
slot only. When not in its assigned time slot, the device
remains in a nonmodulating condition. This enables the
Interrogator to communicate with other devices in the
same Interrogator field with fewer chances of data
collision.
Fast Read Request (FRR): If the TF bit (bit 30
or Block 0) is cleared, the device responds only
to the FRR command. The FRR command
consists of five specially timed gap pulses (refer
to Figures 6-3 to 6-7). The position of the five
gap pulses in the given time span (1.575 ms)
determines the parameters of the command.
The command has three parameters: TCMAX,
TSMAX and Data transmission speed. The
details of these parameters will be discussed in
the following sections. If the device receives the
FRR command, it sends the FR response
and then listens for 1 ms (TLW) for a matching
code from the Interrogator.
Fast Read Bypass (FRB): This command is
used in the Reactivation loop and is only applicable to a device with the FR bit (bit 31 in Block
0) cleared. The device responds with 64 bits of
data, which includes Block 1 data (32-bit Tag
ID), and then listens for 1 ms (TLW) for a matching code from the Interrogator. The command
structure is the same as the FRR command: five
specially timed gap pulses (1.575 ms). The
command parameter (Figure 6-8) determines
the data rate (normal speed or fast speed) of
subsequent Interrogator commands.
Matching Code 1 (MC1): This command
consists of time calibration pulses (TCP)
followed by 1-of-16 PPM signals. It is used when
the device does not need any further processing. This MC1 command causes a device, which
is in the detection loop, to enter the sleeping
loop.
DS40232H-page 16
Matching Code 2 (MC2): The command
structure is the same as MC1: TCP followed by
1-of-16 PPM signals. The command is used
when the device needs further processing (read/
write). The device enters the processing loop if
it receives this command in the detection loop.
5.
End Process (EP): This command consists of
the time reference pulses followed by
1-of-16 PPM signals. The EP command causes
a device to exit the processing loop and enter
the sleeping loop.
6.1.1
DETECTION LOOP
If the FR bit (bit 31 of Block 0) is set, the device can
enter this loop in two ways, depending on the condition
of the TF bit (bit 30 of Block 0). They are:
1.
2.
When the TF bit is cleared, the device enters
this loop and waits for a FRR command. This is
called the “Interrogator-Talks-First” (ITF) mode.
When the TF bit is set, the device enters this
loop by transmitting the FR response without
waiting for an FRR command. This is called the
“Tag-Talks-First” (TTF) mode.
For case 1 above, the parameters of the FRR are:
• Maximum number of time slots
(TSMAX = 1, 16, or 64),
• Maximum transmission counter
(TCMAX = 1, 2, or 4),
• Data transmission speed (Normal or Fast mode).
The purpose of the TSMAX and TCMAX parameters is
to acknowledge the device in the detection loop as fast
as possible. TSMAX represents the maximum number
of time slots between the end of the FRR command and
the beginning of the FR response. One time slot
(TSLOT) represents 2.5 ms. For example, TSMAX = 64
represents a maximum time delay of 160 ms before
sending the FR response. See Section 6.3 “Time
Slot Generator” for the calculation of actual time
delay. TCMAX represents the maximum number of FR
responses a device can send after an FRR command.
For example, TCMAX = 4 means the device can send
its FR response four times (after the FRR command)
for acknowledgment (matching code).
 2003 Microchip Technology Inc.
MCRF450/451/452/455
The TSMAX and TCMAX values are determined by the
Interrogator’s decision on how many tags are in the
field. The Interrogator may assign TSMAX = 1 and
TCMAX = 1, assuming there is only one tag in the field.
The efficiency of the detection will increase in multiple
tag environments by assigning a higher number to both
the TSMAX and TCMAX. If the device receives the
FRR, it clears the Position 1 flag, waits for its time slot,
replies with the FR response and then listens for 1 ms.
The FR response consists of a maximum of 160
Manchester data bits (default: 96 bits), which includes
the 32-bit Tag ID and the FRF data (Blocks 3-5) (see
Table 6-3 and Example 9-1).
To acknowledge the FR response, the Interrogator can
start to send a matching code (MC) during the device’s
1 ms listening window (TLW). The MC is encoded with
1-of-16 PPM signal (see Figure 6-9). The MC1 is given
to the device if the device does not need any further
processing. If the device receives the MC1, it enters the
sleeping loop and stays in the loop in a nonmodulating
condition. The MC2 command is given to the device if
further processing (read/write) is required. If the device
receives the MC2 command, it enters the processing
loop.
If the device misses the MC within the listening window,
it sends the FR response again after its time slot when
two conditions are met: (1) Position 1 flag is cleared
and, (2) TCMAX has not elapsed. The device checks
the condition (elapsed or not elapsed) of TCMAX using
an internal transmission counter (TC). The TC consists
of 3 bits. If the Position 1 flag is cleared, the device
increments the TC by 1 each time it does not receive a
MC during its listening window. See Figure 6-1 for a
flow chart showing the conditional incrementing of the
transmission counter. Table 6-1 shows an example of
detecting the elapsed TCMAX using a rolling modulo-8
transmission counter.
For the TTF case, the device repeats its FR response
(as long as it is energized) according to the TCMAX
and TSMAX parameters, as specified in Table 7-5.
Even though the device is operating in the TTF mode,
it will respond to its correct MC during its listening
window. If TCMAX = 1, 2 or 4, it will also respond to
FRR commands, just as in the ITF case (see
Section 6.1.1.1 “Matching Code Queuing”).
6.1.1.1
Matching Code Queuing
queuing takes place within the detection loop and is
controlled by the conditions of "Set Position 1 Flag" and
TCMAX.
This queuing allows the Interrogator to communicate
with a device outside its listening window. The result is
enhanced and accelerated processing of individual
devices in a multiple tag environment.
TABLE 6-1:
CONDITIONS FOR
TCMAX = ELAPSED FOR ITF
MODE
Rolling
Modulo -8 TC
TCMAX
=1
TCMAX
=2
TCMAX
=4
0
0
1
elapsed
—
—
0
1
0
elapsed
elapsed
—
0
1
1
elapsed
—
—
1
0
0
elapsed
elapsed
elapsed
1
0
1
elapsed
—
—
1
1
0
elapsed
elapsed
—
1
1
1
elapsed
—
elapsed
0
0
0
elapsed
elapsed
—
6.1.2
PROCESSING LOOP
The reading and writing processes take place in this
loop. Devices in this loop are waiting for commands for
processing. In order to read from, or write to, the
device, its “Processing Flag” (PF) must be set. Any
device entering this loop with its PF cleared is called a
“follow-along” tag. This follow-along tag in the loop is
not processed for reading or writing.
If the device with the PF flag set receives the EP
command, it exits this loop and enters the sleeping
loop. However, the same EP command sends the
follow-along tag back to the detection loop.
If the device receives the FRR or FRB command in this
loop, it sees the command as invalid, resets itself and
goes back to the initial power-up state.
6.1.3
SLEEPING LOOP
The sleeping loop is used to keep all processed
devices in a “silent” condition. The devices stay in this
loop in a nonmodulating condition as long as they
remain in the field.
Once the device receives the FRR command, it sends
the FR response and waits for a matching code (MC)
during its listening window. If the device does not
receive its correct MC code before its TCMAX has
elapsed (see Table 6-1), it goes back to the beginning
of the detection loop (position 1 in the loop) and waits
for either a new FRR command or for the MC1 or MC2
matching code. This is called “matching code queuing”.
In this queuing, the device stays in the detection loop
waiting for an Interrogator command (FRR or MC). This
 2003 Microchip Technology Inc.
DS40232H-page 17
MCRF450/451/452/455
6.1.4
REACTIVATION LOOP
The reactivation loop is used to process a device with
its FR bit cleared. A device in this loop waits for the
FRB command. If a device receives the FRB
command, it transmits the contents of Block 1 (Tag ID)
to its memory and waits for a MC2 in its listening
window. If the device receives the MC2, it leaves this
loop and enters the processing loop. This reactivation
loop has no anti-collision capability. It is designed for
reactivation of single devices. This loop can be
effectively used in retail store applications to process
returning items from customers.
DS40232H-page 18
 2003 Microchip Technology Inc.
MCRF450/451/452/455
FIGURE 6-1:
ANTI-COLLISION FLOW CHART
DETECTION
No
Power-up
in Tuned State
TC=0
Set Processing Flag
FR Bit
Set
?
Yes
Talk-First
Bit Set?
No
No
No
FRR
Command?
PPM
Symbol?
No 1
Yes
TC > 0?
Yes
Yes
Yes
Clear Position 1 Flag
REACTIVATION
Set Position 1 Flag
Decode FRR Command
Listen for FRB Command
No
Wait 1, 16, or 64 Time Slot
FRB
Received?
Send FRR Response
(Tag ID + FRF data)
Yes
Send FRB Response
(Tag ID: Block 1 Data)
Yes
No
Listening
Window
Expired?
Listening
Window Expired?
No
Yes
Increment
Transmission
Counter (TC)
Receiving?
Yes
3 PPM
Symbols?
No
Yes
No
3 PPM
Symbols?
No
3rd Symbol
=MC2?
No
Correct Matching
Code?
Yes
Yes
Yes
No
No
Correct
Matching
Code?
Decode Command
at Correct Speed
No
3rd Symbol
=MC2?
Clear Processing Flag
Correct
Matching
Code?
Yes
No Processing
Flag Set?
Yes
Yes
Yes
Wait for Commands
Position 1
Flag Set?
No
3rd Symbol
=MC1?
PROCESSING
Yes
Yes
No
Receiving?
Execute
Command
TCMAX
ELAPSED
?
No
No
No
Yes
No
Yes
Set Processing Flag
Valid
Command?
Yes
Yes
Read or Write
Command?
No
End
Command?
Maintain
Logic State
No
No
Yes
Processing
Flag Set?
Yes
(Do not listen to
any command)
SLEEPING
 2003 Microchip Technology Inc.
DS40232H-page 19
MCRF450/451/452/455
6.2
Anti-collision Command
Controller
This section discusses the anti-collision algorithm and
describes the communications between the
Interrogator and device.
6.2.1
STRUCTURE OF READ/ WRITE
COMMAND SIGNALS
The Interrogator’s Read/Write commands have the
following structure:
Read/Write command = Command + Address + Data + Parity (or CRC)
The commands are summarized in the table below:
TABLE 6-2:
READ/WRITE COMMANDS FROM INTERROGATOR TO DEVICE
Interrogator
Command
Command
Code
Address
Data
Parity or CRC
Symbol
Length
Unused
0xx
xxxxx
—
—
—
Read 32-bit block
110
aaaaa
—
Parity
3 symbols
Unused
111
00xxx
—
—
—
Unused
111
0100x
—
—
—
End Process
111
01010
—
Parity
3 symbols
Unused
111
01011
—
—
—
Unused
111
011xx
—
—
—
Unused
111
1000x
—
—
—
Set Talk First Bit
111
10010
—
Parity
3 symbols
Set FR Bit
111
10011
—
Parity
3 symbols
Clear Talk First Bit
111
10100
—
Parity
3 symbols
Clear FR Bit
111
10101
—
Parity
3 symbols
Unused
111
1011x
—
—
—
Unused
111
11xxx
—
—
—
Unused
100
xxxxx
—
—
—
Write 32-bit block
101
aaaaa
32 bits
CRC-16
14 symbols
Legend: aaaaa = Block address
x = don’t care
Note:
• Command and address are sent MSN (Most
Significant nibble) first.
• Data and parity/CRC are sent LSN (Least
Significant nibble) first.
• Calculation of Parity and CRC includes Command
code, Address, and Data.
• See Microchip Application Note AN752
(DS00752) for the CRC-16 calculation algorithm.
DS40232H-page 20
 2003 Microchip Technology Inc.
MCRF450/451/452/455
6.2.2
STRUCTURE OF DEVICE
RESPONSE
Device Response of Interrogator’s Read command
for Blocks 0 and 2:
When the device receives the Interrogator command, it
responds with 70 kHz Manchester encoded data
having the following structures:
Preamble (8 bits) + Block Number (5 bits) + ‘000’ +
Block Data (32 bits) + Calculated 16 bit CRC (CCRC).
Note: The CCRC is calculated by using block number
and block data only. Preamble and ‘000’ are not
included in the CRC calculation.
Device Response to FRR Command: Preamble (8
bits) + TC (3 bits) + TP (4 bits) + ‘0’ + 32 bits of Tag ID
(Block 1 data) + FRF data (32 - 96 bits) + Calculated
CRC (SCRC, 16 bits) of Tag ID and FRF data = 96 - 160
bits depending on FRF data length.
Device Response of Interrogator’s Read Command
for all other blocks:
Device Response = Preamble (8 bits) + Block Number
(5 bits) + ‘000’ + Block Data (32 bits) + Stored CRC
(SCRC, 16 bits) in the same block.
Note: The preamble + TC + TP + ‘0’ are not included
for the CRC calculation.
Device Response to FRB Command: Preamble (8
bits) + ‘00001’ + ‘000’ + 32 bits of Tag ID (Block 1 data)
+ Stored CRC (SCRC, 16 bits) of Block 1 = 64 bits.
TABLE 6-3:
INTERROGATOR COMMANDS AND DEVICE RESPONSES
Interrogator Command
Delay
Device Response
Read Block 0 and Block 2
data
TDECODE
Preamble, block #, ‘000’, block data, CCRC
Read block data except for
Block 0 and Block 2
TDECODE
Preamble, block #, ‘000’, block data, SCRC
Write block data
TWRITE
For Blocks 0 and 2: Preamble, block #, ‘000’, block data, CCRC
For all others: Preamble, block #, ‘000’, block data, SCRC
Set Fast Read (FR) bit
TWRITE
Preamble, 1 byte ‘0’s, Block 0 data, CCRC
Clear Fast Read (FR) bit
TWRITE
Preamble, 1 byte ‘0’s, Block 0 data, CCRC
Set Talk First (TF) bit
TWRITE
Preamble, 1 byte ‘0’s, Block 0 data, CCRC
Clear Talk First (TF) bit
TWRITE
Preamble, 1 byte ‘0’s, Block 0 data, CCRC
End Process (EP)
FRR
TDECODE
Preamble
f(TSMAX, TCMAX, 8-bit Tag ID) Preamble,TC, TP, ‘0’, Tag ID, FRF, FRR_CCRC
FRB
TDECODE
Preamble, address of block #1 (‘00001’), ‘000’, Tag ID (32 bits),
SCRC of Block 1
References used in this table are as follows:
Preamble = 11111110 (8 bits).‘0’ is transmitted last.
Block # = 5 bit addressed block, transmits Least Significant bit (LSb) first.
Block data = 32-bit data of the addressed block, transmits LSb first.
CCRC = Calculated CRC of the preceding block number and block data. Transmits LSb first.
SCRC = Stored CRC. This SCRC is the CRC of the Write command, address, and data from the Interrogator, LSb first. The device
stores the received CRC for each block. See Section 7.2 “Stored CRC (SCRC) Memory Section” for details.
FRR_CRC = Calculated CRC of 32-bit Tag ID and fast read field (FRF) data.
TP = Tag parameters (4 bits: ‘0’, DF0, DF1, parity). where DF0 and DF1 determine the FR field length (see Table 7-6).
TC = Transmission counter (3 bits), transmits LSb first.
Parity = Even parity bit of TC and TP.
Tag ID = 32 bits of unique identification code of the device, transmits LSb first. This Tag ID is preprogrammed in the factory prior to
shipping.
8-bit Tag ID = 8 bits of Tag ID selected from the 32 bits of the unique tag identification code. Transmits LSb first (see Section 6.2.3.6
“Calculation Of Matching Code” for selecting the 8 bits from the Tag ID).
FRF = Fast Read Field (Blocks 3-5), transmits LSb first (see Section 7.0 “Memory Section”).
f(TSMAX, TCMAX, 8-bit Tag ID = Delay is a function of the TSMAX, TCMAX and 8-bit Tag ID.
TWRITE = Writing time for EEPROM (see Table 2-3).
TDECODE = Time requirement for command decoding (see Table 2-3).
Examples are given in Section 9.0 “Examples”.
 2003 Microchip Technology Inc.
DS40232H-page 21
MCRF450/451/452/455
6.2.3
DETECTION OF INTERROGATOR
COMMANDS
The Interrogator sends commands to the device by
amplitude modulating the carrier signal (gap pulse).
The Interrogator uses two classes of encoding signals
for modulation. They are (1) 1-of-16 PPM for data
transmission, and (2) specially timed gap pulse
sequence for the FRR and FRB commands. These
commands consist of five gap pulses within nine possible gap pulse positions (1.575 ms). The combination of
the possible gap positions determines the command
type and parameters of the Fast Read command.
(FRB) in the Reactivation loop. See Tables 6-5 and 6-6
for the FRR gap pulse positions. See Figures 6-3 to 6-8
for the gap modulation patterns.
The parameters of FRR are: (1) number of time slots
(TSMAX = 1,16, or 64), (2) maximum transmission
counter (TCMAX) and (3) data transmission speed.
The FRB has only a data transmission speed parameter (Normal or Fast Speed mode). The device extracts
these parameters based on the positions of the five gap
pulses within the 1.575 ms time span, as shown in
Figures 6-3 to 6-8.
The Interrogator also sends TCP prior to the 1-of16 PPM. The TCP is used to calibrate the time-base of
the decoder in the device. The specifics of the two
encoding methods and the TCP are described in the
following sections.
TSMAX = 1 is given if there is only one device in the
field. This is called “Conveyor mode” or “single tag
environment”. In this mode, the device responds with
the FR response signal in every time slot until it
receives a correct matching code, or until TCMAX is
elapsed.
6.2.3.1
6.2.3.2
Fast Read (FR) Commands
The FR commands are composed of five 175 µs wide
gap pulses (see Figure 6-2) whose spacing within
1.575 ms determines the command type and its parameters. Table 6-4 shows the specification of the gap
signal for the FR commands. Two commands are used
for the fast read. They are: (1) Fast Read Request
(FRR) in the Detection loop, and (2) Fast Read Bypass
TABLE 6-4:
The Interrogator can send data with two different data
rates: (1) Normal and (2) Fast Speed modes. The
normal speed uses 2.8 ms/symbol, while the fast
speed uses 160 µs/symbol. One symbol represents
one 4-bit data packet (see Section 6.2.3.4 “1-of-16
PPM”). The data transmission speed is a parameter of
the FRR and FRB commands. This parameter
indicates the data speed of subsequent Interrogator
commands. The data rate of the device output (70 kHz)
is not affected by this parameter.
SPECIFICATION OF GAP SIGNAL FOR FRR AND FRB COMMANDS
Number of gaps for one command
Total available number of gap positions within the command time span
Command time span
Gap pulse width
DS40232H-page 22
Data Transmission Speed
5
9
1.575 ms
175 µs
 2003 Microchip Technology Inc.
MCRF450/451/452/455
TABLE 6-5:
SPECIFICATION OF MODULATION SEQUENCE FOR FRR COMMAND
Maximum Time Slot
(TSMAX)
TCMAX
Gap Pulse Position
Data Transmission Mode
1
1
1, 2, 3, 4, 6
Normal Speed
1, 3, 5, 6, 8
Fast Speed
1, 2, 3, 4, 5
Normal Speed
1, 3, 5, 6, 7
Fast Speed
1, 2, 3, 5, 6
Normal Speed
1, 3, 5, 7, 8
Fast Speed
2
4
16
1
2
4
64
TABLE 6-6:
1
1, 2, 4, 6, 8
Normal Speed
1, 3, 4, 6, 8
Fast Speed
1, 2, 4, 6, 7
Normal Speed
1, 3, 4, 6, 7
Fast Speed
1, 2, 4, 5, 6
Normal Speed
1, 3, 4, 5, 6
Fast Speed
1, 2, 4, 5, 7
Normal Speed
1, 3, 4, 5, 7
Fast Speed
SPECIFICATION OF MODULATION SEQUENCE FOR FRB COMMAND
Symbol
Gap Pulse Position
Data Transmission Mode
FRB_N
1, 2, 3, 5, 7
Normal Speed
FRB_F
1, 3, 5, 7, 9
Fast Speed
 2003 Microchip Technology Inc.
DS40232H-page 23
MCRF450/451/452/455
FIGURE 6-2:
PULSE WAVEFORM OF GAP AND 1-OF-16 PPM SIGNALS
t1
100%
t2
50%
B
0%
A
(a)
Example of Interrogator’s signal received at tag’s antenna coil.
See Table 6-7 for the specifications of t1, t2, and modulation depth (modulation index).
The Modulation Index is defined as:
A–B
Modulation Index = ------------- × 100%
A+B
B
A
(b) FRR command waveform for Figure 6-3 (A) with near 100% Modulation Index
B
A
(c) FRR command waveform for Figure 6-3 (A) with near 20% Modulation Index
TABLE 6-7:
WAVEFORM CHARACTERISTICS OF GAP AND 1-0F-16 PPM SIGNALS
Signal
Symbol
Min
Typ
Gap signal and
1-of-16 PPM for
Normal mode
t1
145
t2
20
MODINDEX_GAP
20
1-of-16 PPM for
Fast mode
DS40232H-page 24
Max
Unit
Conditions
175
205
µs
PWPPM_N
100
150
µs
Measured at 50%, See Figure 6-2
GAPWIDTH_N
60
100
%
See Figure 6-2
t1
8.3
10
11.7
µs
PWPPM_F
t2
6.0
7.0
8.0
µs
Measured at 50%, See Figure 6-2
GAPWIDTH_F
MODINDEX_GAP
20
60
100
%
See Figure 6-2
 2003 Microchip Technology Inc.
MCRF450/451/452/455
The following figures show the various modulation
patterns of the Fast Read commands (FRR and FRB).
Each command consists of a combination of five gap
pulses within nine possible gap positions. The pulse
width of each gap is 175 µs and the total time span of
each command for the nine possible positions is
1.575 ms (175 µs x 9 = 1.575 ms).
FIGURE 6-3:
In the figures, Pmn represents mth gap pulse at nth gap
position in the given data packet (symbol).
GAP MODULATION PATTERNS FOR FRR, NORMAL SPEED, TSMAX = 1
(µs)
1
(A) TCMAX = 1
0.5
P11
P22
P33
P44
P56
0
200
600
400
800
1000
1200
1400
1600
(µ s)
1
(B) TCMAX = 2
0.5
P11
P22
P33
P44
P55
0
200
600
400
800
1000
1200
1400
1600
(µs)
1
(C) TCMAX = 4
0.5
P11
P22
P33
P45
P56
800
1000
0
200
FIGURE 6-4:
400
600
1200
1400
1600
GAP MODULATION PATTERNS FOR FRR, FAST SPEED, TSMAX = 1
(µs)
1
(A) TCMAX = 1
0.5
P11
P23
P35
P46
800
1000
P58
0
200
400
600
1400
1200
1600
(µs)
1
(B) TCMAX = 2
0.5
P11
P23
P35
P46
800
1000
P57
0
200
400
600
1400
1200
1600
(µs)
1
(C) TCMAX = 4
0.5
P11
P23
P35
P47
P58
0
200
 2003 Microchip Technology Inc.
400
600
800
1000
1200
1400
1600
DS40232H-page 25
MCRF450/451/452/455
FIGURE 6-5:
GAP MODULATION PATTERNS FOR FRR, NORMAL SPEED, TSMAX = 16
(µs)
1
(A) TCMAX = 1
0.5
P11
P22
P34
P46
P58
0
800
600
400
200
1000
1200
1600
1400
(µs)
1
(B) TCMAX = 2
0.5
P11
P22
P34
P46
P57
0
800
600
400
200
1000
1200
1600
1400
(µs)
1
(C) TCMAX = 4
0.5
P11
P22
P34
P45
P56
800
1000
0
FIGURE 6-6:
600
400
200
1200
1600
1400
GAP MODULATION PATTERNS FOR FRR, FAST SPEED, TSMAX = 16
(µs)
1
(A) TCMAX = 1
0.5
P11
P23
P34
P46
P58
0
600
400
200
800
1000
1200
1600
1400
(µs)
1
(B) TCMAX = 2
0.5
P11
P23
P34
P46
P57
0
600
400
200
800
1000
1200
1600
1400
(µs)
1
(C) TCMAX = 4
0.5
P11
P23
P34
P45
P56
800
1000
0
FIGURE 6-7:
600
400
200
1200
1400
1600
GAP MODULATION PATTERNS FOR FRR, TSMAX = 64, TCMAX = 1
(µs)
1
(A) NORMAL SPEED
0.5
P11
P22
P34
P45
P57
0
200
400
600
800
1000
1200
1400
1600
(µs)
1
(B) FAST SPEED
0.5
P11
P23
P34
P45
P57
0
200
DS40232H-page 26
400
600
800
1000
1200
1400
1600
 2003 Microchip Technology Inc.
MCRF450/451/452/455
FIGURE 6-8:
GAP MODULATION PATTERNS FOR FRB (FAST REQUEST BYPASS)
(µs)
1
(A) NORMAL SPEED
0.5
P11
P23
P33
P45
P57
0
200
400
600
800
1000
1200
1600
1400
(µs)
1
(B) FAST SPEED
0.5
P11
P23
P35
P47
P59
0
200
 2003 Microchip Technology Inc.
400
600
800
1000
1200
1400
1600
DS40232H-page 27
MCRF450/451/452/455
6.2.3.3
Usage Of TSMAX And TCMAX
recommended FRR command repeat times for each of
the 7 possible combinations of TSMAX and TCMAX.
The command repeat time in Table 6-8 is calculated by:
The parameters of TSMAX and TCMAX are
determined by an expected number of tags in the
Detection Loop. The following table shows the
EQUATION 6-1:
COMMAND REPEAT TIME
Command Repeat Time = TSMAX × TCMAX × 2.5ms × 1.17
Where:
1.17 is related to the tolerance of the baud rate.
TABLE 6-8:
FRR COMMAND REPEAT TIME VS. (TSMAX, TCMAX)
(TSMAX, TCMAX)
(1,1)
(1,2)
(1,4)
(16,1)
(16,2)
(16,4)
(64,1)
Command Repeat Time
2.925 ms
5.85 ms
11.7 ms
46.8 ms
93.6 ms
187.2 ms
187.2 ms
6.2.3.4
1-of-16 PPM
The Interrogator uses 1-of-16 Pulse Position
Modulation (PPM) for MC1 and MC2 matching codes,
End Process (EP) and also commands in Table 6-2.
1-of-16 PPM uses only one gap pulse in one of
sixteen possible pulse positions for sending 4-bit
symbols
(24 = 16). This means one symbol (one
data packet) represents 4 bits of binary data. One
symbol lasts for 2.8 ms and 160 µs for Normal Speed
and Fast Speed mode, respectively. All communications begin with time calibration pulses (TCP)
composed of three pulses in positions, zero, six and
fourteen of a 1-of-16 PPM symbol, as shown in
Figure 6-10.
TABLE 6-9:
1-OF-16 PPM PULSE SPECIFICATIONS
Normal Mode
Modulation depth (MODINDEX_GAP)
Fast Mode
100% (max)
100% (max)
Pulse width
175 µs (typical)
10 µs (typical)
Gap width
100 µs (typical)
7 µs (typical)
16
16
Pulse positions per symbol
Symbol width
Calibration sequence
DS40232H-page 28
2.8 ms (typical)
160 µs (typical)
Pulses in positions 0, 6, 14
Pulses in positions 0, 6, 14
 2003 Microchip Technology Inc.
MCRF450/451/452/455
FIGURE 6-9:
Hex
Value
0
1-OF-16 PPM REPRESENTATION FOR HEX VALUES FOR NORMAL SPEED MODE
175
350
525
700
875
1050
1225
1400
4
5
6
7
8
1575 1750 1925
2100
(µs)
2450 2675 2800
2275
PWPPM_N
“0”
“1”
“2”
“3”
“4”
“5”
“6”
“7”
“8”
“9”
“A”
“B”
“C”
“D”
“E”
“F”
Gap
Position
Order
0
1
2
 2003 Microchip Technology Inc.
3
9
10
11
12
13
14
15
DS40232H-page 29
MCRF450/451/452/455
6.2.3.5
Calibration Of Time Reference For
Decoding
The device uses TCP to match its internal decoder
timing to the Interrogator timing. The Interrogator
transmits the timing pulses at the start of all
commands and at least every 17 symbols. The TCP
uses a code violation of the 1-of-16 PPM signal
consisting of three gap pulses within one symbol. The
first gap pulse is located at position 0, the second gap
pulse at position 6 and the third at position 14 of the
symbol. The time period between the last two gap
pulses is used to calibrate the device’s timing for
decoding. Figure 6-10 shows the calibration pulses
for Normal Speed mode. The waveform of the gap
pulses is the same as the 1-of-16 PPM signal, as
shown in Figure 6-2. For Fast Speed mode, the gap
positions are the same. PWPPM_F is the gap pulse
width and SWPPM_F is the symbol width of the Fast
mode.
FIGURE 6-10:
CALIBRATION PULSES FOR NORMAK SPEED MODE
(ms)
Gap Pulse Width
(PWPPM_N)
1
Calibration Time Reference
0.5
0
500
1500
1000
Position 0
2000
Position 6
2500
3000
Position 14
Symbol Width
(SWPPM_N)
6.2.3.6
Calculation Of Matching Code
When the Interrogator receives the FR response from
a device, it sends an MC to select the device. The MC
is sent during the device’s listening window. There are
two different types of matching codes: MC1 and MC2.
Both MC1 and MC2 are used in the detection loop.
MC2 is used in the reactivation loop, as detailed in
Figure 6-1. The MC1 command is used to send the
device to the sleeping loop, while MC2 is used to send
the device to the processing loop.
The MC is an 8-bit “match” of tag ID followed by 4-bit
matching code type and parity bit such that:
DS40232H-page 30
Matching code (12 bits) = “match (8 bits of tag
ID)” + matching code type (3 bits)+ parity (1-bit)
The matching code type and parity bit is bit-wise
structured as follows:
• MC1: 010P
• MC2: 100P
where P represents the parity bit of all match bits (8
bits) plus the MC type (3 bits).
The “match” part of the MC is 8 bits of the 32-bit Tag ID.
The Interrogator selects the 8 bits from the 32-bit Tag
ID by calculating the bit range of the Tag ID.
Equation 6-2 shows the equation for selecting the bit
range using the transmission counter (TC). Both the
 2003 Microchip Technology Inc.
MCRF450/451/452/455
32-bit Tag ID and TC are included in the FR response.
An example for the calculation of the matching code is
given in Example 9-2.
EQUATION 6-2:
BIT-WISE EQUATION FOR
“MATCH”
“Match” = Tag ID bit range a: b
{4*TC} modulo 32: {4 (TC +1) + 3} modulo 32
where {} modulo 32 means the remainder of {}
divided by 32. For example, {28} modulo 32 and {35}
modulo 32 are 28 and 3, respectively.
EQUATION 6-3:
6.3
Time Slot Generator
This block generates time slots for the device. The time
slot represents the time delay between the end of the
FRR command and the beginning of the FR response.
The available time slots are 1, 16 or 64. One time slot
represents 2.5 ms. The device calculates the actual
time slot based on the TSMAX, TC and Tag ID. The
maximum time slot (TSMAX) is assigned to the device
by the FRR command (see Figures 6-3 to 6-7), or set
to 16, if the TF bit is set.
Four or six bits out of the 32-bit Tag ID are used to
calculate the time slot, with TC being the shift
parameter to choose which portion of the 32-bit Tag ID
is used, as shown in Equation 6-3.
TIME SLOT CALCULATION
TSMAX
Time Slot = Tag ID bit range a:b
Note:
64
{[4(TC+1)+1] modulo 32: [4 TC] modulo 32} XOR TC LSB
16
{[4(TC+1)-1] modulo 32: [4 TC] modulo 32} XOR TC LSB
1
0
The exclusive-or (XOR) operation in Equation 6-3 is called “semi-inverting” in that it randomizes worst case
tag IDs; for example: a Tag ID of ‘77777777’ or ‘00000000’. Table 6-10 shows examples of the
calculation.
TABLE 6-10:
EXAMPLE: TAG ID = h´825FE1A0
Selected Tag ID before
XOR with LSB of TC
Relevant Tag ID
TC
TSMAX = 16 TSMAX = 64
Calculated Time Slot (TS)
(after XOR with LSB of TC)
Hexadecimal
Binary
TSMAX = 16
TSMAX = 64
0
h´825FE1(A0)´
b’1010 0000’
h´0´
h´20´
h´0´
d´0´
h´20´
d´32´
1
h´825FE(1A)0´
b’0001 1010’
h´A´
h´1A´
h´5´
d´5´
h´25´
d´37´
2
h´825F(E1)A0´
b’1110 0001’
h´1´
h´21´
h´1´
d´1´
h´21´
d´33´
3
h´825(FE)1A0´
b’1111 1110’
h´E´
h´3E´
h´1´
d´1´
h´01´
d´1´
4
h´82(5F)E1A0´
b’0101 1111’
h´F´
h´1F´
h´F´
d´15´
h´1F´
d´31´
5
h´8(25)FE1A0´
b’0010 0101’
h´5´
h´25´
h´A´
d´10´
h´1A´
d´26´
6
h´(82)5FE1A0´
b’1000 0010’
h´2´
h´02´
h´2´
d´2´
h´02´
d´2´
7
h´(08)25FE1A´
b’0000 1000’
h´8´
h´08´
h´7´
d´7´
h´37´
d´55´
Legend: h´x..x´ represents hexadecimal number
d´x..x´ represents decimal number
b´x..x´ represents binary number
Table 6-10 shows the calculated time slot (TS): 5 for
TC = 1 and TSMAX = 16 with Tag ID = h´825FE1A0´.
This means the device waits for 12.5 ms (5 x 2.5 ms =
12.5 ms) in a nonmodulating condition between the
end of FRR and the start of the FR response.
6.4
TIME SLOT COUNTER
This section generates the Sleep time (2.5 ms x TS) of
the device. During the Sleep time, the device remains
in a nonmodulating condition.
Also, the TS is 37 for TC = 1 and TSMAX = 64. This
means the device waits for 92.5 ms (37 x 2.5 ms =
92.5 ms) between the end of FRR and the start of the
FR response in a nonmodulating condition.
 2003 Microchip Technology Inc.
DS40232H-page 31
MCRF450/451/452/455
7.0
MEMORY SECTION
7.2
The memory section is organized into two groups: Main
Memory Section and Stored CRC (SCRC) Memory
Section.
7.1
Main Memory Section
The main section is organized into 32 blocks, as shown
in Table 7-1, with each block having 32 bits. Each
individual block can be read and written by the Interrogator’s command. The first Blocks (0-2) are used for
predefined parameters and device operation. The next
three Blocks (3-5) are used as the FRF data.
The Blocks from 3 to 31 (29 blocks) are used for user
data memory. Bits from 0 to 15 of Block 0 also can be
used for user memory. The memory is read or written in
32-bit selectable units. The exceptions are the FR bit
and the TF bit of Block 0, which are individually
selectable.
Each block is accessed by the Interrogator’s command
based on block address. The reading of FRF blocks
(Blocks 3-5) can be accomplished in two different
ways: (1) by FRR command or (2) by Read Block
command. The device sends the FRF data when it
receives the FRR command. The length of the FRF
data for the FRR command is determined by DF bits
(see Table 7-6).
TABLE 7-1:
Stored CRC (SCRC) Memory
Section
This memory section is used to store the CRC of the
main memory section. It is organized into 32 blocks.
Each block has 16 bits and contains the CRC of the
corresponding memory block.
The Stored CRC (SCRC) is the CRC of the Interrogator’s writing command (Write command + block
address + data). The device stores the received
Interrogator’s CRC and sends back verification when it
sends the block data. For the Block 0 and 2, the device
sends CCRC instead of the SCRC. The device sends
the CRC of each block as follows:
• Blocks 0 and 2: CCRC of block number and block
data.
• Other blocks except Block 0 and 2: SCRC.
• CRC for FRR response: CCRC of Tag ID and FRF
(Blocks 3-5) data. The data length of the FRF is
determined by DF bits (B0: 26-27).
MEMORY ORGANIZATION
Main Memory Section
(32 blocks x 32 bits)
Stored CRC Section
(32 blocks x 16 bits)
M
S
B
Comments
L1111119876543210
S543210
B
FT T
RF F
T
D M
F T
Byte 3
T
M
Available to user
(21 Bits)
Byte 2
Byte 1
Block 0
(Tag Parameters + User Memory)
Byte 0
33222222222211111111119876543210
1098765432109876543210
Fast
Read
Field
Fast
Read
Field
Fast
Read
Field
Block 1 (Tag ID = Serial Number)
Block 2 (Write Protection bits)
(Clear bit 2 to write-protect Block 2)
(LS Block)
Block 3 (FR Field Least Significant
Block)
(MS Block)
Block 5 (FR Field Most Significant
Block)
Block 4 (FR Field)
Block 6 (User Data)
Block 7 (User Data)
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
Block 31 (User Data)
DS40232H-page 32
 2003 Microchip Technology Inc.
MCRF450/451/452/455
7.3
Bit Layout
7.3.1
BLOCK 0
The bit layout in Block 0 is given in the following table.
FR and TF bits are not write-protectable.
TABLE 7-2:
BIT LAYOUT OF BLOCK 0
B0:31
FR
B0:23
TM2*
B0:15
B0:30
B0:29
B0:28
B0:27
B0:26
B0:25
B0:24
TF
TFT1
TFT0
DF1
DF0
MT1*
MT0*
B0:22
B0:21
B0:20
B0:19
B0:18
B0:17
B0:16
TM1*
TM0*
B0:14
B0:13
B0:10
B0:9
B0:8
B0:2
B0:1
B0:0
User Memory
B0:12
B0:11
User Memory
B0:7
B0:6
B0:5
B0:4
B0:3
User Memory
Note:
* These are ‘hardwired’ bits, not EEPROM bits.
7.3.1.1
Description Of Bits
TABLE 7-3:
FR BIT (B0:31)
Reply to FRR
(Fast Read Request) Command
Reply to FRB
(Fast Read Bypass) Command
0
No
Yes
(see Example 9-1 for response)
“Item” has been purchased in
retail EAS applications.
1
Yes
(see Example 9-1 for response)
No
“Item” is unpaid in retail EAS
applications.
FR
Note:
Application Example
FR bit is not write-protectable.
TABLE 7-4:
TF BIT (B0:30)
TF
Condition
0
Interrogator-Talks-First (ITF) mode: Wait for FRR command for FRR Response.
1
Tag-Talks-First (TFT) mode if FR bit is also set: Send Fast Read response without waiting for FRR
command.
Note:
TF bit is not write-protectable.
TABLE 7-5:
TFT1
TFT0
0
0
0
1
1
1
Note 1:
2:
TFT BITS (B0:29 - B0:28)
TCMAX 1
for Tag-Talks-First mode
TABLE 7-6:
DF BITS (B0:27 - B0:26)
DF1
DF0
FR Data Field Length
1
0
0
32 bits (Default)
2
0
1
48 bits
0
4
1
0
64 bits
1
Never Elapses (Default) 2
1
1
96 bits
Only applicable in TTF mode. TSMAX
parameter is set to 64 for TTF mode. For
the ITF mode, the TCMAX is given in the
FRR command.
The device continuously sends its FR
response until it receives its correct
matching code. On average, the device
will send its FR response every 80 ms.
 2003 Microchip Technology Inc.
DS40232H-page 33
MCRF450/451/452/455
TABLE 7-7:
MT BITS (B0:25 - B0:24)
MT1
MT0
Memory Type
0
0
Single level EEPROM (Default).
0
1
Reserved for future uses
(e.g., multi level EEPROM).
1
0
Reserved for future uses.
1
1
Reserved for future uses.
Note:
The MT bits are “hardwired”.
TABLE 7-8:
TM BITS (B0:23 - B0:21)
TM2
TM1
TM0
0
0
0
512 bits
0
0
1
1 Kbit (Default)
0
1
0
TBD
0
1
1
TBD
1
0
0
TBD
1
0
1
TBD
1
1
0
TBD
1
1
TBD
1
Note:
WRITE-PROTECT
Bit X of Write-Protect
Block
Block X Write Status
Block X writable
1
Block X write-protected
0
7.3.4
BLOCKS 3 - 5: FAST READ FIELDS
These blocks contain data bits for the FR response.
The state of the DF bits (see Table 7-6) in Block 0
determines the actual number of bits to be sent. This
block can be used both as a customer ID and as
additional tag ID numbers. These blocks are called
Fast Read Field (FRF) because the device sends the
FRF data immediately following the FRR command
only (ITF mode), or as soon as energized (TTF mode),
without an additional Block Read command. This
means that the reading of this FRF data can be done
by FRR command only. Reading of other block data
requires the FRR and Block Read commands. Only the
FRR device (FR bit = set) outputs the FRF data. The
FRB device (FR bit = cleared) does not send the FRF
data.
The TM bits are “hardwired”.
TABLE 7-9:
B0:(20-0)
7.3.2
Total Memory Size
TABLE 7-10:
B0: (20-0)
Available for user
BLOCK 1: UNIQUE 32-BIT TAG ID
Block 1 contains 32 bits of unique Tag ID with SCRC.
The ID is uniquely serialized by Microchip Technology
Inc.
7.3.3
BLOCK 2: WRITE-PROTECT FOR
THE FIRST KBITS
Each bit corresponds to a 32-bit block, (i.e., bit ‘0’ to
Block 0, bit ‘1’ to Block 1, etc.). Program the
corresponding bit to ‘0’ to write-protect the block. For
example, program bit 10 to ‘0’ to write-protect the Block
10. The initial value (default) of Block 2 is ‘FFFFFFFD’.
This means Block 1 (Tag ID) is write-protected before
shipping to customer.
Write protection is a one way process, (i.e., once a
block is write-protected, it cannot be modified). It
should be noted that the write-protect block itself can
be write-protected. TF and FR bits in Block 0 are not
write-protectable, even if the write protection bit in the
block is set.
DS40232H-page 34
 2003 Microchip Technology Inc.
MCRF450/451/452/455
8.0
DEVICE TESTING
The device will be shipped to customers with the FR bit
set, and with Block 1 write-protected.
The following bits are factory programmed prior to
shipping:
1.
2.
3.
4.
DF0 (B0:26) and DF1(B0:27) are set to ‘0’s.
TFT0 (B0:28) and TFT1(B0:29) bits are set to
‘1’s.
All bits in the FR field (Blocks 3-5) are
programmed to ‘1’s.
Failed device in the Test mode: (1) Tag ID is
programmed with "BADBADBA" and (2) inked
with black color on the die (see Section 10.0
“Failed Die Identification”, for the failed die
identification).
 2003 Microchip Technology Inc.
DS40232H-page 35
MCRF450/451/452/455
9.0
EXAMPLES
EXAMPLE 9-1:
READ/WRITE PULSE SEQUENCE
To write 1 block (32 bits) in Normal mode with TS = 1: ~ 78.014 ms
To read 1 block (32 bits) in Normal mode with TS = 1: ~ 42.214 ms
FRR or FRB Command
(5 gap pulses = 1.575 ms)
Interrogator
Command
(FRR or FRB)
t
For FRR Response:
(Preamble (8 bits) + TC (3 bits) + TP (4 bits) + ‘0’ + 32 bits of Tag ID
+ FRF (32-96 bits) + CCRC of Tag ID and FRF data
= 160 bits max = 2.286 ms)
For FRB Response:
(Preamble (8 bits) + ‘00001’ + ‘000’ + 32-bit Tag ID (Block 1 data)
+ SCRC (16 bits)
= 64 bits = 0.914 ms)
TDECODE
(1.225 ms)
Time Slot
(TS)
Tag Response
(FR response)
Listening window (TLW) for 1 ms
t
Matching Code during listening window:
MC code = Calibration pulse (1 symbol) + Matched Tag ID (8 bits)
+ MC code type (3 bits) + 1 Parity bit
= Cal. pulse (1 symbol) + 12 bits = 4 symbols = 11.2 ms
Interrogator
Command
(MC and
Read/Write)
t
Twrite
for EEPROM
For Reading: Cal. pulse (1 symbol) + Read Command (MSN first)
(5 ms)
+ Address (MSN first + Parity) = Cal. pulse + 3 symbols = 11.2 ms
For Writing: Cal. pulse (1 symbol) + Write Command (MSN first)
+ Address (MSN first) + data (LSN first) + Parity/CRC (LSN first)
= Cal. pulse (1 symbol) + 14 symbols = 42 ms
Tag Response
(to Read/Write)
t
Device Outputs:
After a completion of write cycle:
Preamble (8 bits) + written block # (5 bits) + ‘000’
+ written block data (32 bits) + CCRC/SCRC (16 bits)
= 64 bits = 0.914 ms
After Read command:
Preamble (8 bits) + block # (5 bits) + ‘000’ + block data (32 bits)
+ CCRC/SCRC (16 bits)
= 64 bits = 0.914 ms
Interrogator
Command
(End Process)
t
End Process Command:
Cal. pulse + End Process Command (‘111’)
+ Address (‘01010’) + Parity (1)
= Cal. Pulse + 3 symbols = 11.2 ms
Tag Response
to End Process
t
Device Response: 8-bit preamble (‘11111110’)
(0.114 ms)
DS40232H-page 36
 2003 Microchip Technology Inc.
MCRF450/451/452/455
EXAMPLE 9-2:
CALCULATION OF MATCHING CODE FOR TAG ID = 825FE1A0 (HEX, MSB
FIRST)
The “match” part of the matching code is calculated by the Bit-Wise Equation in Equation 6-2:
“Match (8 bits)” = Tag ID bit range a:b = {4(TC)}modulo 32: {4(TC + 1) + 3} modulo 32
For TC = 2, the above equation gives a = 8, and b = 15.
The “Match (8 bits)” is chosen from (8th 9th 10th 11th) and (12th 13th 14th 15th) bits of the Tag ID.
Therefore, for the Tag ID = 825FE1A0 (hex) = b/1000 0010 0101 1111 1110 0001 1010 0000/,
“Match (8 bits)” = b/1110 0001/ = 1E (hex).
Using this “Match” part, a complete set of matching code is assembled as:
1E5 for MC1, and
1E9 for MC2
where:
5 in the MC1 was from b/0101/ (010 for MC1 and the last ‘1’ is a parity bit),
9 in the MC2 was from b/1001/ (100 for MC2 and the last ‘1’ is a parity bit).
Gap position in the 1-of-16 PPM signal for the calculated MC codes:
The gap position numbers in the 1-of-16 PPM for the calculated MC codes are (see Figure 6-9 for 1-of-16 PPM):
Positions 1, 14, and 5 for 1E5 for MC1 code
Positions 1, 14, and 9 for 1E9 for MC2 code.
The “Match” part of the matching code for various TCs are given in Table 9-1.
TABLE 9-1:
CALCULATED “MATCH” FOR TAG ID = 825FE1A0 (HEX)
TC
“Match (8 bits) in hex”
0
0A
1
A1
2
1E
3
EF
4
F5
5
52
6
28
7
80
 2003 Microchip Technology Inc.
DS40232H-page 37
MCRF450/451/452/455
EXAMPLE 9-3:
TO WRITE DATA INTO THE DEVICE
The Interrogator command structure for writing (see Section 6.2.1 “Structure of Read/ Write Command Signals”) is:
Calibration pulse + Writing Command (MSN first) + Address (MSN first) + Data (LSN first) + Parity/CRC (LSN first)
If the Interrogator wants to write data “0123cdef (hex, MSB to LSB)” to Block 5, the following message will be sent:
Calibration pulse + Write Command (MSN first) + Address (MSN first) + Data (LSN first) + Parity/CRC (LSN first)
= Cal. pulse + 101 (Write command) + 00101 (address) + f e d c 3 2 1 0 (data, hex) + CRC
= Calibration pulse + a 5 f e d c 3 2 1 0 6 0 2 e (hex string)
Note:
CRC = CRC for the Write command, address, and data. Calibration pulse is not included for the CRC
calculation. See Application Note AN752 (DS00752) for the CRC calculation algorithm.
The hex string above is encoded with the 1-of-16 PPM signals. See Figure 6-10 for the 1-of-16 PPM representation of
hex values.
Referring to Figure 6-10, the gap positions in the 1-of-16 PPM for the above hex string are:
Positions 10 (a), 5 (5), 15 (f), 14 (e), 13 (d), 12 (c), 3 (3), 2 (2), 1 (1), 0 (0), 6 (6), 0 (0), 2 (2), e (14).
Device Response:
1.
2.
3.
4.
If writing is completed: The device sends the written data after 5 msec of EEPROM writing time.
If writing is failed due to insufficient programming voltage for unprotected block: The device sends the current
block data after about 500 µsec of delay.
If writing is failed because the block is write-protected block: The device sends the current block data immediately
after the command.
If writing is failed due to incorrect CRC: The device does not respond at all.
FIGURE 9-1:
FLOW CHART FOR THE DEVICE RESPONSE TO THE WRITE COMMAND
Wait for
Command
Received
Yes
Write Command?
Yes
Is CRC
Correct?
No
No
Read and Send
EEPROM
Block Data
Yes
Is the Block
Write-Protected?
No
No
Have sufficient
High Voltage for
programming?
Start High Voltage
and Wait for about
500 µsec
Yes
Write EEPROM
Data (5 msec)
DS40232H-page 38
 2003 Microchip Technology Inc.
MCRF450/451/452/455
EXAMPLE 9-4:
TO READ DATA FROM THE DEVICE
To read the content of Block 5 that has been programmed in the previous example, the Interrogator sends the following
command:
Calibration pulse + Read Command (‘110’) + Address (‘00101’) + Parity (‘0’)
= Calibration pulse + C50 (hex)
The gap positions in the 1-of-16 PPM signal for the above hex string are:
12 (C), 5 (5), 0 (0).
Device Response:
When the device receives the above Interrogator command, the device outputs the following 70 kHz Manchester
encoded data string (see Section 6.2.2 “Structure of Device Response”):
Preamble (8 bits) + Block number (5 bits, LSB first) + ‘000’ + Block Data (32 bits, LSB first) + SCRC (16 bits)
= 1-1-1-1-1-1-1-0 (f7) + 1-0-1-0-0-0-0-0 (5 0) + 1-1-1-1 0-1-1-1 1-0-1-1... 1-0-0-0
0-0-0-0 (f e d c 3 2 1 0) + 0-1-1-0 0-0-0-0 0-1-0-0 0-1-1-1 (602e).
EXAMPLE 9-5:
TO SEND THE “END PROCESS” COMMAND
The Interrogator command structure (see Section 6.2 “Anti-collision Command Controller”) for the End Process is:
Calibration pulse + End Process Command (‘111’) + Address (‘01010’) + Parity (1) = Calibration pulse + EA1 (hex)
The gap positions in the 1-of-16 PPM signal for the above hex string are:
14 (E), 10 (A), 1 (1).
Device Response:
The device outputs the 8-bit preamble (‘11111110’) when it receives the End Process command, and enters the
Sleeping Loop.
 2003 Microchip Technology Inc.
DS40232H-page 39
MCRF450/451/452/455
10.0
FAILED DIE IDENTIFICATION
Every die on the wafer is electrically tested according
to the data sheet specifications and visually inspected
to detect any mechanical damage, such as mechanical
cracks and scratches.
Any failed die in the test or visual inspection is identified
by black colored ink. Therefore, any die covered with
black ink should not be used.
The ink dot specification:
• Ink dot size: 254 µm in circular diameter
• Position: central third of die
• Color: black
11.0
WAFER DELIVERY
DOCUMENTATION
The wafer is shipped with the following information:
•
•
•
•
•
•
Microchip Technology Inc. MP Code
Lot Number
Total number of wafers in the container
Total number of good dice in the container
Average die per wafer (DPW)
Scribe number of wafers with number of good
dice
12.0
The device is very susceptible to Electrostatic
Discharge (ESD), which can cause a critical damage to
the device. Special attention is needed during the
handling process.
Any ultraviolet (UV) light can erase the memory cell
contents of an unpackaged device. Fluorescent lights
and sunlight can also erase the memory cell, although
it takes more time than UV lamps. Therefore, keep any
unpackaged device out of UV light and also avoid direct
exposure of strong fluorescent lights and shining
sunlight.
Certain IC manufacturing, COB, and tag assembly
operations may use UV light. Operations such as backgrind de-tape, certain cleaning procedures, epoxy or
glue cure should be done without exposing the die
surface to UV light.
Using X-ray for die inspection will not harm the die, nor
erase memory cell contents.
13.0
REFERENCES
It is recommended that the reader reference the
following documents.
1.
2.
3.
4.
5.
DS40232H-page 40
NOTICE ON DIE AND WAFER
HANDLING
“Antenna Circuit Design for RFID Applications”,
AN710, DS00710.
“RFID Tag and COB Development Guide with
Microchip’s RFID Devices”, AN830, DS00830.
“CRC Algorithm for MCRF45X Read/Write
Devices”, AN752, DS00752.
“Interface Control Document for 13.56 MHz
Anti-collision Interrogator”, AN759, DS00759.
“13.56 MHz Reader Reference Design for the
MCRF450/451/452/455 Read/Write Devices”,
DS21654.
 2003 Microchip Technology Inc.
MCRF450/451/452/455
14.0
PACKAGING INFORMATION
14.1
Package Marking Information
8-Lead PDIP (300 mil)
XXXXXXXX
XXXXXNNN
YYWW
8-Lead SOIC (150 mil)
XXXXXXXX
XXXXYYWW
NNN
Legend:
Note:
*
XX...X
YY
WW
NNN
Example:
MCRF450
237
0025
Example:
MCRF450
0025
237
Customer specific information*
Year code (last 2 digits of calendar year)
Week code (week of January 1 is week ‘01’)
Alphanumeric traceability code
In the event the full Microchip part number cannot be marked on one line, it will
be carried over to the next line thus limiting the number of available characters
for customer specific information.
Standard device marking consists of Microchip part number, year code, week code, and traceability code.
For device marking beyond this, certain price adders apply. Please check with your Microchip Sales
Office. For QTP devices, any special marking adders are included in QTP price.
 2003 Microchip Technology Inc.
DS40232H-page 41
MCRF450/451/452/455
Package Marking Information (Continued)
MCRF45X COB
1.42
5.00
1.06
∅2.00
R0.20
R1.30
31.84
Y
0.80(2X)
35.00
9.65
0.60(4X)
5.10
6.88
6.27
5.21
X
9.65
9.65
0.40 (max.)
R0.16 (2X)
1.42
0.60(2X)
1.58
Detail X
4.23
1.50
9.50
1.85
9.50
0.40
8.00
1.53(4X)
9.50
4.75
9.65
9.65
4.90
0.30 (ref.)
5.90
2.52
3.75
Note 2
1.94
5.60
R0.20(4X)
Legend:
Note:
*
4.75
XX...X
YY
WW
NNN
3.88
Note:
1. Reject hole by device testing
2. Top gate mark (Option)
3. Total package thickness excludes
punching burr
2.375
Customer specific information*
Year code (last 2 digits of calendar year)
Week code (week of January 1 is week ‘01’)
Alphanumeric traceability code
In the event the full Microchip part number cannot be marked on one line, it will
be carried over to the next line thus limiting the number of available characters
for customer specific information.
Standard device marking consists of Microchip part number, year code, week code, and traceability code.
For device marking beyond this, certain price adders apply. Please check with your Microchip Sales
Office. For QTP devices, any special marking adders are included in QTP price.
DS40232H-page 42
 2003 Microchip Technology Inc.
MCRF450/451/452/455
8-Lead Plastic Dual In-line (P) – 300 mil (PDIP)
E1
D
2
n
1
α
E
A2
A
L
c
A1
β
B1
p
eB
B
Units
Dimension Limits
n
p
Number of Pins
Pitch
Top to Seating Plane
Molded Package Thickness
Base to Seating Plane
Shoulder to Shoulder Width
Molded Package Width
Overall Length
Tip to Seating Plane
Lead Thickness
Upper Lead Width
Lower Lead Width
Overall Row Spacing
Mold Draft Angle Top
Mold Draft Angle Bottom
* Controlling Parameter
§ Significant Characteristic
A
A2
A1
E
E1
D
L
c
§
B1
B
eB
α
β
MIN
.140
.115
.015
.300
.240
.360
.125
.008
.045
.014
.310
5
5
INCHES*
NOM
MAX
8
.100
.155
.130
.170
.145
.313
.250
.373
.130
.012
.058
.018
.370
10
10
.325
.260
.385
.135
.015
.070
.022
.430
15
15
MILLIMETERS
NOM
8
2.54
3.56
3.94
2.92
3.30
0.38
7.62
7.94
6.10
6.35
9.14
9.46
3.18
3.30
0.20
0.29
1.14
1.46
0.36
0.46
7.87
9.40
5
10
5
10
MIN
MAX
4.32
3.68
8.26
6.60
9.78
3.43
0.38
1.78
0.56
10.92
15
15
Notes:
Dimensions D and E1 do not include mold flash or protrusions. Mold flash or protrusions shall not exceed
.010” (0.254mm) per side.
JEDEC Equivalent: MS-001
Drawing No. C04-018
 2003 Microchip Technology Inc.
DS40232H-page 43
MCRF450/451/452/455
8-Lead Plastic Small Outline (SN) – Narrow, 150 mil (SOIC)
E
E1
p
D
2
B
n
1
h
α
45°
c
A2
A
φ
β
L
Units
Dimension Limits
n
p
Number of Pins
Pitch
Overall Height
Molded Package Thickness
Standoff §
Overall Width
Molded Package Width
Overall Length
Chamfer Distance
Foot Length
Foot Angle
Lead Thickness
Lead Width
Mold Draft Angle Top
Mold Draft Angle Bottom
* Controlling Parameter
§ Significant Characteristic
A
A2
A1
E
E1
D
h
L
φ
c
B
α
β
MIN
.053
.052
.004
.228
.146
.189
.010
.019
0
.008
.013
0
0
A1
INCHES*
NOM
8
.050
.061
.056
.007
.237
.154
.193
.015
.025
4
.009
.017
12
12
MAX
.069
.061
.010
.244
.157
.197
.020
.030
8
.010
.020
15
15
MILLIMETERS
NOM
8
1.27
1.35
1.55
1.32
1.42
0.10
0.18
5.79
6.02
3.71
3.91
4.80
4.90
0.25
0.38
0.48
0.62
0
4
0.20
0.23
0.33
0.42
0
12
0
12
MIN
MAX
1.75
1.55
0.25
6.20
3.99
5.00
0.51
0.76
8
0.25
0.51
15
15
Notes:
Dimensions D and E1 do not include mold flash or protrusions. Mold flash or protrusions shall not exceed
.010” (0.254mm) per side.
JEDEC Equivalent: MS-012
Drawing No. C04-057
DS40232H-page 44
 2003 Microchip Technology Inc.
MCRF450/451/452/455
ON-LINE SUPPORT
Microchip provides on-line support on the Microchip
World Wide Web site.
The web site is used by Microchip as a means to make
files and information easily available to customers. To
view the site, the user must have access to the Internet
and a web browser, such as Netscape® or Microsoft®
Internet Explorer. Files are also available for FTP
download from our FTP site.
Connecting to the Microchip Internet
Web Site
SYSTEMS INFORMATION AND
UPGRADE HOT LINE
The Systems Information and Upgrade Line provides
system users a listing of the latest versions of all of
Microchip's development systems software products.
Plus, this line provides information on how customers
can receive the most current upgrade kits. The Hot Line
Numbers are:
1-800-755-2345 for U.S. and most of Canada, and
1-480-792-7302 for the rest of the world.
042003
The Microchip web site is available at the following
URL:
www.microchip.com
The file transfer site is available by using an FTP
service to connect to:
ftp://ftp.microchip.com
The web site and file transfer site provide a variety of
services. Users may download files for the latest
Development Tools, Data Sheets, Application Notes,
User's Guides, Articles and Sample Programs. A
variety of Microchip specific business information is
also available, including listings of Microchip sales
offices, distributors and factory representatives. Other
data available for consideration is:
• Latest Microchip Press Releases
• Technical Support Section with Frequently Asked
Questions
• Design Tips
• Device Errata
• Job Postings
• Microchip Consultant Program Member Listing
• Links to other useful web sites related to
Microchip Products
• Conferences for products, Development Systems,
technical information and more
• Listing of seminars and events
 2003 Microchip Technology Inc.
DS40232H-page 45
MCRF450/451/452/455
READER RESPONSE
It is our intention to provide you with the best documentation possible to ensure successful use of your Microchip product. If you wish to provide your comments on organization, clarity, subject matter, and ways in which our documentation
can better serve you, please FAX your comments to the Technical Publications Manager at (480) 792-4150.
Please list the following information, and use this outline to provide us with your comments about this document.
To:
Technical Publications Manager
RE:
Reader Response
Total Pages Sent ________
From: Name
Company
Address
City / State / ZIP / Country
Telephone: (_______) _________ - _________
FAX: (______) _________ - _________
Application (optional):
Would you like a reply?
Y
Device: MCRF450/451/452/455
N
Literature Number: DS40232H
Questions:
1. What are the best features of this document?
2. How does this document meet your hardware and software development needs?
3. Do you find the organization of this document easy to follow? If not, why?
4. What additions to the document do you think would enhance the structure and subject?
5. What deletions from the document could be made without affecting the overall usefulness?
6. Is there any incorrect or misleading information (what and where)?
7. How would you improve this document?
DS40232H-page 46
 2003 Microchip Technology Inc.
MCRF450/451/452/455
PRODUCT IDENTIFICATION SYSTEM
To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office.
PART NO.
Device
Device:
X
Temperature
Range
Package
13.56 MHz Anti-collision Read/Write
MicroID device w/no internal resonant
capacitor
MCRF450/7M: COB (Chip-On-Board) module with dual
68 pF capacitor
MCRF451:
13.56 MHz Anti-collision Read/Write
MicroID device w/100 pF internal
resonant capacitor
MCRF452:
13.56 MHz Anti-collision Read/Write
MicroID device w/25 pF internal resonant
capacitor
MCRF455:
13.56 MHz Anti-collision Read/Write
MicroID device w/50 pF internal resonant
capacitor
Examples:
a)
MCRF450/W: 13.56 MHz Anti-collision
Read/Write MicroID device, 1 Kbit, no cap, 8"
wafer, 11-mil backgrind.
b)
MCRF450/7M: 13.56 MHz Anti-collision
Read/Write MicroID COB (IST IOA2), 1 Kbit,
68 pF dual capacitor between antenna A and B,
antenna B and VSS. Thickness = 0.4 mm.
c)
MCRF451/WF: 13.56 MHz Anti-collision
Read/Write MicroID device, 1 Kbit, 100 pF
internal res cap, 8" wafer on frame, 8 mil
backgrind.
d)
MCRF451/S:
13.56 MHz Anti-collision
Read/Write MicroID device in waffle pack,
1 Kbit, 100 pF internal res cap, 8-mil
thickness.
e)
MCRF452/WFB: 13.56 MHz Anti-collision
Read/Write MicroID bumped device for flipchip assembly, 1 Kbit, 50 pF dual (25 pF)
internal res cap, Bumped 8" wafer, 8-mil
backgrind wafer on frame.
f)
MCRF455X/SN: 13.56 MHz Anti-collision
Read/Write MicroID device in SOIC package,
1k bit, 50 pF internal res cap.
MCRF450:
Temperature Range:
Package:
/XX
=
WF
WFB
W
WB
S
SB
X/SN
P
-20°C to +70°C
= Sawed 8" wafer on frame (8 mil backgrind)
= Bumped, sawed 8" wafer on frame (8 mil
backgrind
= 8" wafer (11 mil backgrind)
= Bumped 8" wafer (8 mil backgrind)
= Dice in waffle pack (8 mil backgrind)
= Bumped die in waffle pack (8 mil backgrind)
= SOIC (150 mil body), 8-lead (rotated pinout)
= PDIP (300 mil body), 8-lead
Sales and Support
Data Sheets
Products supported by a preliminary Data Sheet may have an errata sheet describing minor operational differences and
recommended workarounds. To determine if an errata sheet exists for a particular device, please contact one of the following:
1.
2.
3.
Your local Microchip sales office
The Microchip Corporate Literature Center U.S. FAX: (480) 792-7277
The Microchip Worldwide Site (www.microchip.com)
Please specify which device, revision of silicon and Data Sheet (include Literature #) you are using.
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 2003 Microchip Technology Inc.
DS40232H-page47
MCRF450/451/452/455
NOTES:
DS40232H-page 48
 2003 Microchip Technology Inc.
Note the following details of the code protection feature on Microchip devices:
•
Microchip products meet the specification contained in their particular Microchip Data Sheet.
•
Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the
intended manner and under normal conditions.
•
There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our
knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip's Data
Sheets. Most likely, the person doing so is engaged in theft of intellectual property.
•
Microchip is willing to work with the customer who is concerned about the integrity of their code.
•
Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not
mean that we are guaranteeing the product as “unbreakable.”
Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our
products. Attempts to break microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts
allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.
Information contained in this publication regarding device
applications and the like is intended through suggestion only
and may be superseded by updates. It is your responsibility to
ensure that your application meets with your specifications.
No representation or warranty is given and no liability is
assumed by Microchip Technology Incorporated with respect
to the accuracy or use of such information, or infringement of
patents or other intellectual property rights arising from such
use or otherwise. Use of Microchip’s products as critical
components in life support systems is not authorized except
with express written approval by Microchip. No licenses are
conveyed, implicitly or otherwise, under any intellectual
property rights.
Trademarks
The Microchip name and logo, the Microchip logo, dsPIC,
KEELOQ, MPLAB, PIC, PICmicro, PICSTART, PRO MATE and
PowerSmart are registered trademarks of Microchip
Technology Incorporated in the U.S.A. and other countries.
FilterLab, microID, MXDEV, MXLAB, PICMASTER, SEEVAL
and The Embedded Control Solutions Company are
registered trademarks of Microchip Technology Incorporated
in the U.S.A.
Accuron, Application Maestro, dsPICDEM, dsPICDEM.net,
ECAN, ECONOMONITOR, FanSense, FlexROM, fuzzyLAB,
In-Circuit Serial Programming, ICSP, ICEPIC, microPort,
Migratable Memory, MPASM, MPLIB, MPLINK, MPSIM,
PICC, PICkit, PICDEM, PICDEM.net, PowerCal, PowerInfo,
PowerMate, PowerTool, rfLAB, rfPIC, Select Mode,
SmartSensor, SmartShunt, SmartTel and Total Endurance are
trademarks of Microchip Technology Incorporated in the
U.S.A. and other countries.
Serialized Quick Turn Programming (SQTP) is a service mark
of Microchip Technology Incorporated in the U.S.A.
All other trademarks mentioned herein are property of their
respective companies.
© 2003, Microchip Technology Incorporated, Printed in the
U.S.A., All Rights Reserved.
Printed on recycled paper.
Microchip received QS-9000 quality system
certification for its worldwide headquarters,
design and wafer fabrication facilities in
Chandler and Tempe, Arizona in July 1999
and Mountain View, California in March 2002.
The Company’s quality system processes and
procedures are QS-9000 compliant for its
PICmicro® 8-bit MCUs, KEELOQ® code hopping
devices, Serial EEPROMs, microperipherals,
non-volatile memory and analog products. In
addition, Microchip’s quality system for the
design and manufacture of development
systems is ISO 9001 certified.
 2003 Microchip Technology Inc.
DS40232H-page 49
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DS40232H-page 50
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07/28/03
 2003 Microchip Technology Inc.
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