Leidos 418M1 RTR-4 Wireless Option User Manual Keeloq Code Hopping Encoder

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Document ID	256525
Application ID	j+wmDyXqU9ldGb0gZTkA4A==
Document Description	manual hcs300
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Document Type	User Manual
Display Format	Adobe Acrobat PDF - pdf
Filesize	53.88kB (673474 bits)
Date Submitted	2002-07-16 00:00:00
Date Available	2002-07-12 00:00:00
Creation Date	1999-10-04 08:06:19
Producing Software	Acrobat Distiller 3.01 for Windows
Document Lastmod	1999-11-16 12:16:36
Document Title	Keeloq Code Hopping Encoder
Document Creator	FrameMaker 5.5.6p145
Document Author:	Fanie Duvenhange

21137e.Book Page 1 Monday, October 4, 1999 8:04 AM
HCS300
KEELOQ® Code Hopping Encoder
FEATURES
DESCRIPTION
Security
The HCS300 from Microchip Technology Inc., is a code
hopping encoder designed for secure Remote Keyless
Entry (RKE) systems. The HCS300 utilizes the ® code
hopping technology, which incorporates high security, a
small package outline and low cost to make this device
a perfect solution for unidirectional remote keyless
entry systems and access control systems.
•
•
•
•
•
•
Programmable 28-bit serial number
Programmable 64-bit encryption key
Each transmission is unique
66-bit transmission code length
32-bit hopping code
34-bit fixed code (28-bit serial number,
4-bit button code, 2-bit status)
• Encryption keys are read protected
PACKAGE TYPES
PDIP, SOIC
Operating
2.0—6.3V operation
Four button inputs
No additional circuitry required
15 functions available
Selectable baud rate
Automatic code word completion
Battery low signal transmitted to receiver
Non-volatile synchronization data
S0
S1
S2
S3
VDD
LED
PWM
VSS
Oscillator
Easy to use programming interface
On-chip EEPROM
On-chip oscillator and timing components
Button inputs have internal pulldown resistors
Current limiting on LED output
Minimum component count
Synchronous transmission mode
Power
latching
and
switching
Controller
Reset circuit
LED
LED driver
EEPROM
Encoder
PWM
32-bit shift register
Typical Applications
The HCS300 is ideal for Remote Keyless Entry (RKE)
applications. These applications include:
•
•
•
•
•
•
HCS300 BLOCK DIAGRAM
Other
•
•
•
•
•
•
•
HCS300
•
•
•
•
•
•
•
•
VSS
Button input port
VDD
Automotive RKE systems
Automotive alarm systems
Automotive immobilizers
Gate and garage door openers
Identity tokens
Burglar alarm systems
S3
S2
S1
S0
KEELOQ is a registered trademark of Microchip Technology, Inc.
Microchip’s Secure Data Products are covered by some or all of the following patents:
Code hopping encoder patents issued in Europe, U.S.A., and R.S.A. — U.S.A.: 5,517,187; Europe: 0459781; R.S.A.: ZA93/4726
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 1
21137e.Book Page 2 Monday, October 4, 1999 8:04 AM
HCS300
The HCS300 combines a 32-bit hopping code
generated by a non-linear encryption algorithm, with a
28-bit serial number and six status bits to create a 66bit transmission stream. The length of the transmission
eliminates the threat of code scanning and the code
hopping mechanism makes each transmission unique,
thus rendering code capture and resend (code grabbing) schemes useless.
The encryption key, serial number, and configuration
data are stored in EEPROM, which is not accessible via
any external connection. This makes the HCS300 a
very secure unit. The HCS300 provides an easy to use
serial interface for programming the necessary security
keys, system parameters, and configuration data.
The encyrption keys and code combinations are programmable but read-protected. The keys can only be
verified after an automatic erase and programming
operation. This protects against attempts to gain
access to keys and manipulate synchronization values.
The HCS300 operates over a wide voltage range of
2.0V to 6.3V and has four button inputs in an 8-pin
configuration. This allows the system designer the
freedom to utilize up to 15 functions. The only
components required for device operation are the buttons and RF circuitry, allowing for a very low
system cost.
1.0
SYSTEM OVERVIEW
Key Terms
• Manufacturer’s code - a 64-bit word, unique to
each manufacturer, used to produce a unique
encryption key in each transmitter (encoder).
• Encryption Key - a unique 64-bit key generated
and programmed into the encoder during the
manufacturing process. The encryption key
controls the encryption algorithm and is stored in
EEPROM on the encoder device.
1.1
Learn
The HCS product family facilitates several learn strategies to be implemented on the decoder. The following
are examples of what can be done. It must be pointed
out that there exists some third-party patents on learning strategies and implementation.
1.1.1
NORMAL LEARN
The receiver uses the same information that is transmitted during normal operation to derive the transmitter’s secret key, decrypt the discrimination value and
the synchronization counter.
DS21137E-page 2
1.1.2
SECURE LEARN*
The transmitter is activated through a special button
combination to transmit a stored 48-bit value (random
seed) that can be used for key generation or be part of
the key. Transmission of the random seed can be disabled after learning is completed.
The HCS300 is a code hopping encoder device that is
designed specifically for keyless entry systems,
primarily for vehicles and home garage door openers.
It is meant to be a cost-effective, yet secure solution to
such systems. The encoder portion of a keyless entry
system is meant to be held by the user and operated to
gain access to a vehicle or restricted area. The
HCS300 requires very few external components
(Figure 2-1).
Most keyless entry systems transmit the same code
from a transmitter every time a button is pushed. The
relative number of code combinations for a low end
system is also a relatively small number. These
shortcomings provide the means for a sophisticated
thief to create a device that ‘grabs’ a transmission and
re-transmits it later or a device that scans all possible
combinations until the correct one is found.
The HCS300 employs the code hopping technology
and an encryption algorithm to achieve a high level of
security. Code hopping is a method by which the code
transmitted from the transmitter to the receiver is
different every time a button is pushed. This method,
coupled with a transmission length of 66 bits, virtually
eliminates the use of code ‘grabbing’ or code
‘scanning’.
As indicated in the block diagram on page one, the
HCS300 has a small EEPROM array which must be
loaded with several parameters before use. The most
important of these values are:
• A 28-bit serial number which is meant to be
unique for every encoder.
• An encryption key that is generated at the time of
production.
• A 16-bit synchronization value.
The serial number for each transmitter is programmed
by the manufacturer at the time of production. The
generation of the encryption key is done using a key
generation algorithm (Figure 1-1). Typically, inputs to
the key generation algorithm are the serial number of
the transmitter and a 64-bit manufacturer’s code. The
manufacturer’s code is chosen by the system
manufacturer and must be carefully controlled. The
manufacturer’s code is a pivotal part of the overall
system security.
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 3 Monday, October 4, 1999 8:04 AM
HCS300
FIGURE 1-1: CREATION AND STORAGE OF ENCRYPTION KEY DURING PRODUCTION
HCS300 EEPROM Array
Transmitter
Serial Number or
Seed
Manufacturer’s
Code
Key
Generation
Algorithm
Encryption
Key
The 16-bit synchronization value is the basis for the
transmitted code changing for each transmission, and
is updated each time a button is pressed. Because of
the complexity of the code hopping encryption algorithm, a change in one bit of the synchronization value
will result in a large change in the actual transmitted
code. There is a relationship (Figure 1-2) between the
key values in EEPROM and how they are used in the
encoder. Once the encoder detects that a button has
been pressed, the encoder reads the button and
updates the synchronization counter. The synchronization value is then combined with the encryption key in
the encryption algorithm and the output is 32 bits of
encrypted information. This data will change with every
button press, hence, it is referred to as the hopping
portion of the code word. The 32-bit hopping code is
combined with the button information and the serial
number to form the code word transmitted to the
receiver. The code word format is explained in detail
in Section 4.2.
 1999 Microchip Technology Inc.
Serial Number
Encryption Key
Sync Counter
Any type of controller may be used as a receiver, but it
is typically a microcontroller with compatible firmware
that allows the receiver to operate in conjunction with a
transmitter, based on the HCS300. Section 7.0
provides more detail on integrating the HCS300 into a
total system.
Before a transmitter can be used with a particular
receiver, the transmitter must be ‘learned’ by the
receiver. Upon learning a transmitter, information is
stored by the receiver so that it may track the
transmitter, including the serial number of the
transmitter, the current synchronization value for that
transmitter and the same encryption key that is used on
the transmitter. If a receiver receives a message of valid
format, the serial number is checked and, if it is from a
learned transmitter, the message is decrypted and the
decrypted synchronization counter is checked against
what is stored. If the synchronization value is verified,
then the button status is checked to see what operation
is needed. Figure 1-3 shows the relationship between
some of the values stored by the receiver and the values received from the transmitter.
Preliminary
DS21137E-page 3
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HCS300
FIGURE 1-2: BASIC OPERATION OF TRANSMITTER (ENCODER)
Transmitted Information
KEELOQ
Encryption
Algorithm
EEPROM Array
32 Bits of
Encrypted Data
Serial Number
Button Press
Information
Encryption Key
Sync Counter
Serial Number
FIGURE 1-3: BASIC OPERATION OF RECEIVER (DECODER)
Check for
Match
EEPROM Array
KEELOQ
Decryption
Algorithm
Encryption Key
Decrypted
Synchronization
Counter
Sync Counter
Serial Number
Check for
Match
Manufacturer Code
Button Press
Information
Serial Number
32 Bits of
Encrypted Data
Received Information
DS21137E-page 4
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 5 Monday, October 4, 1999 8:04 AM
HCS300
2.0
DEVICE OPERATION
TABLE 2-1:
As shown in the typical application circuits (Figure 2-1),
the HCS300 is a simple device to use. It requires only
the addition of buttons and RF circuitry for use as the
transmitter in your security application. A description of
each pin is described in Table 2-1.
FIGURE 2-1: TYPICAL CIRCUITS
PIN DESCRIPTIONS
Name
Pin
Number
S0
Switch input 0
S1
Switch input 1
S2
Switch input 2/Can also be clock
pin when in programming mode
S3
Switch input 3/Clock pin when in
programming mode
VDD
B0
S0
B1
VSS
Ground reference connection
PWM
Pulse width modulation (PWM)
output pin/Data pin for
programming mode
LED
Cathode connection for directly
driving LED during transmission
VDD
Positive supply voltage
connection
VDD
S1
LED
S2
PWM
S3
VSS
Tx out
2 button remote control
VDD
B4 B3 B2 B1 B0
S0
VDD
S1
LED
S2
PWM
S3
VSS
Tx out
5 button remote control (Note)
Note:
Description
Up to 15 functions can be implemented by pressing more than one button simultaneously or by
using a suitable diode array.
The high security level of the HCS300 is based on the
patented technology. A block cipher type of encryption
algorithm based on a block length of 32 bits and a key
length of 64 bits is used. The algorithm obscures the
information in such a way that even if the transmission
information (before coding) differs by only one bit from
the information in the previous transmission, the next
coded transmission will be totally different. Statistically,
if only one bit in the 32-bit string of information
changes, approximately 50 percent of the coded transmission will change. The HCS300 will wake up upon
detecting a switch closure and then delay approximately 10 ms for switch debounce (Figure 2-2). The
synchronized information, fixed information, and switch
information will be encrypted to form the hopping code.
The encrypted or hopping code portion of the transmission will change every time a button is pressed, even if
the same button is pushed again. Keeping a button
pressed for a long time will result in the same code
word being transmitted, until the button is released or
timeout occurs. A code that has been transmitted will
not occur again for more than 64K transmissions. This
will provide more than 18 years of typical use before a
code is repeated, based on 10 operations per day.
Overflow information programmed into the encoder can
be used by the decoder to extend the number of unique
transmissions to more than 192K.
If in the transmit process it is detected that a new button(s) has been pressed, a reset will immediately be
forced and the code word will not be completed. Please
note that buttons removed will not have any effect on
the code word unless no buttons remain pressed in
which case the current code word will be completed
and the power down will occur.
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 5
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HCS300
3.0
FIGURE 2-2: ENCODER OPERATION
EEPROM MEMORY
ORGANIZATION
Power Up
(A button has been pressed)
Reset and Debounce Delay
(10 ms)
Sample Inputs
The HCS300 contains 192 bits (12 x 16-bit words) of
EEPROM memory (Table 3-1). This EEPROM array is
used to store the encryption key information,
synchronization value, etc. Further descriptions of the
memory array is given in the following sections.
TABLE 3-1:
Update Sync Info
Yes
WORD
ADDRESS
EEPROM MEMORY MAP
MNEMONIC
DESCRIPTION
Encrypt With
Encryption Key
KEY_0
64-bit encryption key
(word 0)
Load Transmit Register
KEY_1
64-bit encryption key
(word 1)
Transmit
KEY_2
64-bit encryption key
(word 2)
KEY_3
64-bit encryption key
(word 3)
SYNC
16-bit synchronization
value
RESERVED
Set to 0000H
SER_0
Device Serial Number
(word 0)
SER_1(Note) Device Serial Number
(word 1)
SEED_0
Seed Value (word 0)
SEED_1
Seed Value (word 1)
10
EN_KEY
16-bit Envelope Key
11
CONFIG
Config Word
Buttons
Added
No
All
Buttons
Released
Yes
No
Complete Code
Word Transmission
Stop
Note:
3.1
The MSB of the serial number contains a bit
used to select the auto shutoff timer.
Key_0 - Key_3 (64-Bit Encryption Key)
The 64-bit encryption key is used by the transmitter to
create the encrypted message transmitted to the
receiver. This key is created and programmed at the
time of production using a key generation algorithm.
Inputs to the key generation algorithm are the serial
number for the particular transmitter being used and a
secret manufacturer’s code. While the key generation
algorithm supplied is the typical method used, a user
may elect to create their own method of key generation.
This may be done, providing that the decoder is programmed with the same means of creating the key for
decryption purposes. If a seed is used, the seed will
also form part of the input to the key generation algorithm.
DS21137E-page 6
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 7 Monday, October 4, 1999 8:04 AM
HCS300
3.2
SYNC (Synchronization Counter)
3.6
This is the 16-bit synchronization value that is used to
create the hopping code for transmission. This value
will be changed after every transmission.
3.3
SER_0, SER_1 (Encoder Serial
Number)
SER_0 and SER_1 are the lower and upper words of
the device serial number, respectively. Although there
are 32 bits allocated for the serial number, only the
lower order 28 bits are transmitted. The serial number
is meant to be unique for every transmitter. The most
significant bit of the serial number (Bit 31) is used to
turn the auto shutoff timer on or off.
3.3.1
The configuration word is a 16-bit word stored in
EEPROM array that is used by the device to store
information used during the encryption process, as well
as the status of option configurations. Further
explanations of each of the bits are described in the
following sections.
TABLE 3-2:
Bit Number
AUTO SHUTOFF TIMER SELECT
The most significant bit of the serial number (Bit 31) is
used to turn the Auto shutoff timer on or off. This timer
prevents the transmitter from draining the battery
should a button get stuck in the on position for a long
period of time. The time period is approximately
25 seconds, after which the device will go to the Timeout mode. When in the Time-out mode, the device will
stop transmitting, although since some circuits within
the device are still active, the current draw within the
Shutoff mode will be more than Standby mode. If the
most significant bit in the serial number is a one, then
the auto shutoff timer is enabled, and a zero in the most
significant bit will disable the timer. The length of the
timer is not selectable.
3.4
This is the two word (32 bits) seed code that will be
transmitted when all four buttons are pressed at the
same time. This allows the system designer to implement the secure learn feature or use this fixed code
word as part of a different key generation/tracking process or purely as a fixed code transmission.
3.5
EN_Key (Envelope Encryption Key)
Envelope encryption is a selectable option that
encrypts the portion of the transmission that contains
the transmitter serial number. Selecting this option is
done by setting the appropriate bit in the configuration
word (Table 3-2). Normally, the serial number is
transmitted in the clear (un-encrypted), but for an
added level of security, the system designer may elect
to implement this option. The envelope encryption key
is used to encrypt the serial number portion of the
transmission, if the envelope encryption option has
been selected. The envelope encryption algorithm is a
different algorithm than the key generation or transmit
encryption algorithm. The EN_key is typically a random
number and the same for all transmitters in a system.
 1999 Microchip Technology Inc.
CONFIGURATION WORD
Bit Description
Discrimination Bit 0
Discrimination Bit 1
Discrimination Bit 2
Discrimination Bit 3
Discrimination Bit 4
Discrimination Bit 5
Discrimination Bit 6
Discrimination Bit 7
Discrimination Bit 8
Discrimination Bit 9
10
Overflow Bit 0 (OVR0)
11
Overflow Bit 1 (OVR1)
12
Low Voltage Trip Point Select
13
Baudrate Select Bit 0 (BSL0)
14
Baudrate Select Bit 1 (BSL1)
15
3.6.1
SEED_0, SEED_1 (Seed Word)
Configuration Word
Envelope Encryption Select (EENC)
DISCRIMINATION VALUE
(DISC0 TO DISC9)
The discrimination value can be programmed with any
value to serve as a post decryption check on the
decoder end. In a typical system, this will be
programmed with the 10 least significant bits of the
serial number, which will also be stored by the receiver
system after a transmitter has been learned. The
discrimination bits are part of the information that is to
form the encrypted portion of the transmission. After
the receiver has decrypted a transmission, the
discrimination bits can be checked against the stored
value to verify that the decryption process was valid.
3.6.2
OVERFLOW BITS (OVR0 AND OVR1)
The overflow bits are used to extend the number of possible synchronization values. The synchronization
counter is 16 bits in length, yielding 65,536 values
before the cycle repeats. Under typical use of
10 operations a day, this will provide nearly 18 years of
use before a repeated value will be used. Should the
system designer conclude that is not adequate, then
the overflow bits can be utilized to extend the number
of unique values. This can be done by programming
OVR0 and OVR1 to 1s at the time of production. The
encoder will automatically clear OVR0 the first time that
the synchronization value wraps from 0xFFFF to
Preliminary
DS21137E-page 7
21137e.Book Page 8 Monday, October 4, 1999 8:04 AM
HCS300
0x0000 and clear OVR1 the second time the counter
wraps. Once cleared, OVR0 and OVR1 cannot be set
again, thereby creating a permanent record of the
counter overflow. This prevents fast cycling of 64K
counter. If the decoder system is programmed to track
the overflow bits, then the effective number of unique
synchronization values can be extended to 196,608. If
programmed to zero, the system will be compatible with
the NTQ104/5/6 devices (i.e., no overflow with discrimination bits set to zero).
3.6.3
FIGURE 3-1:
TYPICAL VOLTAGE TRIP
POINTS
Volts (V)
VLOW
4.2
VLOW sel = 1
4.0
3.8
3.6
2.6
ENVELOPE ENCRYPTION (EENC)
2.4
VLOW sel = 0
2.2
If the EENC bit is set to a 1, the 32-bit fixed code part
of the transmission will also be encrypted so that it will
appear to be random. The 16-bit envelope key and
envelope algorithm will be used for encryption.
2.0
1.8
1.6
1.4
3.6.4
BAUDRATE SELECT BITS (BSL0, BSL1)
BSL0 and BSL1 select the speed of transmission and
the code word blanking. Table 3-3 shows how the bits
are used to select the different baud rates and
Section 5.2 provides detailed explanation in code word
blanking.
TABLE 3-3:
BAUDRATE SELECT
BSL1
BSL0
Basic Pulse
Element
Code Words
Transmitted
400µs
200µs
100µs
100µs
All
1 out of 2
1 out of 2
1 out of 4
3.6.5
LOW VOLTAGE TRIP POINT SELECT
The low voltage trip point select bit is used to tell the
HCS300 what VDD level is being used. This information
will be used by the device to determine when to send
the voltage low signal to the receiver. When this bit is
set to a one, the VDD level is assumed to be operating
from a 5 volt or 6 volt VDD level. If the bit is set low, then
the VDD level is assumed to be 3.0 volts. Refer to
Figure 3-1 for voltage trip point.VLOW is tested at 6.3V
at -25°C and +85°C and 2.0V at -25°C and +85°C
-40
50
85
4.0
TRANSMITTED WORD
4.1
Transmission Format (PWM)
Temp (C)
The HCS300 transmission is made up of several parts
(Figure 4-1). Each transmission is begun with a
preamble and a header, followed by the encrypted and
then the fixed data. The actual data is 66 bits which
consists of 32 bits of encrypted data and 34 bits of fixed
data. Each transmission is followed by a guard period
before another transmission can begin. Refer to
Table 8-4 for transmission timing requirements. The
encrypted portion provides up to four billion changing
code combinations and includes the button status bits
(based on which buttons were activated) along with the
synchronization counter value and some discrimination
bits. The fixed portion is comprised of the status bits,
the function bits and the 28-bit serial number. The fixed
and encrypted sections combined increase the number
of combinations to 7.38 x 1019.
4.2
Synchronous Transmission Mode
Synchronous transmission mode can be used to clock
the code word out using an external clock.
To enter synchronous transmission mode, the programming mode start-up sequence must be executed
as shown in Figure 4-3. If either S1 or S0 is set on the
falling edge of S2 (or S3), the device enters synchronous transmission mode. In this mode, it functions as a
normal transmitter, with the exception that the timing of
the PWM data string is controlled externally and 16
extra bits are transmitted at the end with the code word.
The button code will be the S0, S1 value at the falling
edge of S2 or S3. The timing of the PWM data string is
controlled by supplying a clock on S2 or S3 and should
not exceed 20 kHz. The code word is the same as in
PWM mode with 16 reserved bits at the end of the
word. The reserved bits can be ignored. When in syn-
DS21137E-page 8
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 9 Monday, October 4, 1999 8:04 AM
HCS300
chronous transmission mode S2 or S3 should not be
toggled until all internal processing has been completed as shown in Figure 4-4.
4.3
Code Word Organization
The HCS300 transmits a 66-bit code word when a button is pressed. The 66-bit word is constructed from a
Fixed Code portion and an Encrypted Code portion
(Figure 4-2).
The Encrypted Data is generated from four button bits,
two overflow counter bits, ten discrimination bits, and
the 16-bit synchronization value (Figure 8-4).
The Fixed Code Data is made up from two status bits,
four button bits, and the 28-bit serial number. The four
button bits and the 28-bit serial number may be
encrypted with the Envelope Key, if the envelope
encryption is enabled by the user.
FIGURE 4-1: CODE WORD TRANSMISSION FORMAT
LOGIC ‘0’
LOGIC ‘1’
Bit
Period
Preamble
TP
Header
TH
Encrypted Portion
of Transmission
THOP
Fixed Portion of
Transmission
TFIX
Guard
Time
TG
FIGURE 4-2: CODE WORD ORGANIZATION
Fixed Code Data
VLOW and
Button
Repeat Status Status
(4 bits)
(2 bits)
Encrypted Code Data
28-bit Serial Number
Button Overflow Discrimination
bits
bits
Status
(10 bits)
(4 bits) (2 bits)
16-bit
Sync Value
Encrypted using
BLOCK CIPHER Algorithm
2 bits
of Status
Serial Number and Button
Status (32 bits)
32 bits of Encrypted Data
Transmission Direction
 1999 Microchip Technology Inc.
Preliminary
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HCS300
FIGURE 4-3: SYNCHRONOUS TRANSMISSION MODE
t = 50 ms
PWM
S2(S3)
“01,10,11”
S[1:0]
FIGURE 4-4: TRANSMISSION WORD FORMAT DURING SYNCHRONOUS TRANSMISSION MODE
Reserved
Padding
Button
Code
Serial Number
Data Word
Sync Counter
16
28
16
16
Transmission Direction
5.0
SPECIAL FEATURES
5.1
Code Word Completion
Code word completion is an automatic feature that
makes sure that the entire code word is transmitted,
even if the button is released before the transmission is
complete. The HCS300 encoder powers itself up when
a button is pushed and powers itself down after the
command is finished, if the user has already released
the button. If the button is held down beyond the time
for one transmission, then multiple transmissions will
result. If another button is activated during a
transmission, the active transmission will be aborted
and the new code will be generated using the new
button information.
5.2
Blank Alternate Code Word
Federal Communications Commission (FCC) Part 15
rules specify the limits on fundamental power and
harmonics that can be transmitted. Power is calculated
on the worst case average power transmitted in a
100ms window. It is therefore advantageous to
minimize the duty cycle of the transmitted word. This
can be achieved by minimizing the duty cycle of the
individual bits and by blanking out consecutive words.
Blank Alternate Code Word (BACW) is used for
reducing the average power of a transmission
(Figure 5-1). This is a selectable feature that is
determined in conjunction with the baudrate selection
bits BSL0 and BSL1. Using the BACW allows the user
to transmit a higher amplitude transmission if the
transmission length is shorter. The FCC puts
DS21137E-page 10
constraints on the average power that can be
transmitted by a device, and BACW effectively prevents
continuous transmission by only allowing the transmission of every second or every fourth code word. This
reduces the average power transmitted and hence,
assists in FCC approval of a transmitter device.
5.3
Envelope Encryption Option
Envelope Encryption is a user selectable option which
is meant to offer a higher level of security for a code
hopping system. During a normal transmission with the
envelope encryption turned off, the 28-bit serial
number is transmitted in the clear (unencrypted). If
envelope encryption is selected, then the serial number
is also encrypted before transmission. The encryption
for the serial number is done using a different algorithm
than the transmission algorithm. The envelope
encryption scheme is not nearly as complex as the
algorithm and, hence, not as secure. When the envelope encryption is used, the serial number must be
decrypted using the envelope key and envelope
decryption. After the serial number is obtained, the normal decryption method can be used to decrypt the hopping code. All transmitters in a system must use the
same envelope key.
5.4
Secure Learn
In order to increase the level of security in a system, it
is possible for the receiver to implement what is known
as a secure learn function. This can be done by utilizing
the seed value on the HCS300 which is stored in
EEPROM and can only be transmitted when all four
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 11 Monday, October 4, 1999 8:04 AM
HCS300
5.5
button inputs are pressed at the same time (Table 5-1).
Instead of the normal key generation method being
used to create the encryption key, this seed value is
used and there need not be any mathematical relationship between serial numbers and seeds.
TABLE 5-1:
The Auto-shutoff function automatically stops the
device from transmitting if a button inadvertently gets
pressed for a long period of time. This will prevent the
device from draining the battery if a button gets pressed
while the transmitter is in a pocket or purse. This function can be enabled or disabled and is selected by setting or clearing the Auto-shutoff bit (see Section 3.3.1).
Setting this bit high will enable the function (turn Autoshutoff function on) and setting the bit low will disable
the function. Time-out period is approximately 25 seconds.
PIN ACTIVATION TABLE
S3
S2
S1
S0
Notes
10
11
12
13
14
15
Note 1: Transmit generated
hopping word.
Auto-shutoff
32-bit
code
2: Transmit 32-bit seed value.
FIGURE 5-1: BLANK ALTERNATE CODE WORD (BACW)
Amplitude
100ms
BACW Disabled
(All words transmitted)
BACW Enabled
(1 out of 2 transmitted)
2A
BACW Enabled
(1 out of 4 transmitted)
4A
One Code Word
100ms
100ms
100ms
Time
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 11
21137e.Book Page 12 Monday, October 4, 1999 8:04 AM
HCS300
5.6
VLOW: Voltage LOW Indicator
The VLOW bit is transmitted with every transmission
(Figure 8-4) and will be transmitted as a one if the
operating voltage has dropped below the low voltage
trip point. The trip point is selectable between two
values, based on the battery voltage being used. See
Section 3.6.5 for a description of how the low voltage
select option is set. This VLOW signal is transmitted so
the receiver can give an audible signal to the user that
the transmitter battery is low (Section 5.8).
5.7
RPT: Repeat Indicator
This bit will be low for the first transmitted word. If a
button is held down for more than one transmitted code
word, this bit will be set to indicate a repeated code
word and remain set until the button is released
(Figure 8-4).
5.8
LED Output Operation
During normal transmission the LED output is LOW. If
the supply voltage drops below the low voltage trip
point, the LED output will be toggled at approximately
5Hz during the transmission (Section 3.6.5).
DS21137E-page 12
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 13 Monday, October 4, 1999 8:04 AM
HCS300
6.0
PROGRAMMING THE HCS300
as the data in line. After each 16-bit word is loaded, a
programming delay is required for the internal program
cycle to complete. This delay can take up to TWC. At the
end of the programming cycle, the device can be verified (Figure 6-2) by reading back the EEPROM. Reading is done by clocking the S3 line and reading the data
bits on PWM. For security reasons, it is not possible to
execute a verify function without first programming the
EEPROM. A verify operation can only be done
once, immediately following the program cycle.
When using the HCS300 in a system, the user will have
to program some parameters into the device including
the serial number and the secret key before it can be
used. The programming cycle allows the user to input
all 192 bits in a serial data stream, which are then
stored internally in EEPROM. Programming will be
initiated by forcing the PWM line high, after the S3 line
has been held high for the appropriate length of time
line (Table 6-1 and Figure 6-1). After the program mode
is entered, a delay must be provided to the device for
the automatic bulk write cycle to complete. This will
write all locations in the EEPROM to an all zeros pattern. The device can then be programmed by clocking
in 16 bits at a time, using S3 as the clock line and PWM
Note:
To ensure that the device does not accidentally enter programming mode, PWM
should never be pulled high by the circuit
connected to it. Special care should be
taken when driving PNP RF transistors.
FIGURE 6-1: PROGRAMMING WAVEFORMS
Enter Program
TPBW
Mode
TDS
TCLKH
TWC
S3
(Clock)
TPS TPH1
TDH
TCLKL
PWM
(Data)
Bit 0
Bit 1
Bit 2
Bit 3
Bit 14
Bit 15
Bit 16
Data for Word 1
Data for Word 0 (KEY_0)
Repeat 12 times for each word
TPH2
Bit 17
Note 1: Unused button inputs to be held to ground during the entire programming sequence.
Note 2: The VDD pin must be taken to ground after a program/verify cycle.
FIGURE 6-2: VERIFY WAVEFORMS
Begin Verify Cycle Here
End of
Programming Cycle
PWM
(Data)
Bit190 Bit191
Bit 0
TWC
Bit 1 Bit 2
Data in Word 0
Bit 3
Bit 14
Bit 15
Bit 16 Bit 17
Bit190 Bit191
TDV
S3
(Clock)
Note: If a Verify operation is to be done, then it must immediately follow the Program cycle.
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 13
21137e.Book Page 14 Monday, October 4, 1999 8:04 AM
HCS300
TABLE 6-1:
PROGRAMMING/VERIFY TIMING REQUIREMENTS
VDD = 5.0V ± 10%
25° C ± 5 °C
Symbol
Min.
Max.
Program mode setup time
Parameter
TPS
3.5
4.5
Units
ms
Hold time 1
TPH1
3.5
—
ms
Hold time 2
TPH2
50
—
µs
Bulk Write time
TPBW
—
2.2
ms
Program delay time
TPROG
—
2.2
ms
Program cycle time
TWC
—
36
ms
Clock low time
TCLKL
25
—
µs
Clock high time
TCLKH
25
—
µs
Data setup time
TDS
—
µs
Data hold time
TDH
18
—
µs
Data out valid time
TDV
10
24
µs
DS21137E-page 14
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 15 Monday, October 4, 1999 8:04 AM
HCS300
7.0
INTEGRATING THE HCS300
INTO A SYSTEM
FIGURE 7-1: TYPICAL LEARN SEQUENCE
Use of the HCS300 in a system requires a compatible
decoder. This decoder is typically a microcontroller with
compatible firmware. Microchip will provide (via a
license agreement) firmware routines that accept
transmissions from the HCS300 and decrypt the
hopping code portion of the data stream. These
routines provide system designers the means to
develop their own decoding system.
7.1
Learning a Transmitter to a Receiver
In order for a transmitter to be used with a decoder, the
transmitter must first be ‘learned’. Several learning
strategies can be followed in the decoder implementation. When a transmitter is learned to a decoder, it is
suggested that the decoder stores the serial number
and current synchronization value in EEPROM. The
decoder must keep track of these values for every
transmitter that is learned (Figure 7-1). The maximum
number of transmitters that can be learned is only a
function of how much EEPROM memory storage is
available. The decoder must also store the manufacturer’s code in order to learn a transmission transmitter,
although this value will not change in a typical system
so it is usually stored as part of the microcontroller
ROM code. Storing the manufacturer’s code as part of
the ROM code is also better for security reasons.
It must be stated that some learning strategies have
been patented and care must be taken not to infringe.
Enter Learn
Mode
Wait for Reception
of a Valid Code
Generate Key
from Serial Number
Use Generated Key
to Decrypt
Compare Discrimination
Value with Fixed Value
Equal
No
Yes
Wait for Reception
of Second Valid Code
Use Generated Key
to Decrypt
Compare Discrimination
Value with Fixed Value
Equal
No
Yes
Counters
Sequential
Yes
No
Learn successful Store:
Learn
Unsuccessful
Serial number
Encryption key
Synchronization counter
Exit
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 15
21137e.Book Page 16 Monday, October 4, 1999 8:04 AM
HCS300
7.2
Decoder Operation
7.3
In a typical decoder operation (Figure 7-2), the key
generation on the decoder side is done by taking the
serial number from a transmission and combining that
with the manufacturer’s code to create the same secret
key that was used by the transmitter. Once the secret
key is obtained, the rest of the transmission can be
decrypted. The decoder waits for a transmission and
immediately can check the serial number to determine
if it is a learned transmitter. If it is, it takes the encrypted
portion of the transmission and decrypts it using the
stored key. It uses the discrimination bits to determine
if the decryption was valid. If everything up to this point
is valid, the synchronization value is evaluated.
FIGURE 7-2: TYPICAL DECODER OPERATION
Start
No
Transmission
Received
Yes
No
Does
Serial Number
Match
The
technology
features
sophisticated
synchronization technique (Figure 7-3) which does not
require the calculation and storage of future codes. If
the stored counter value for that particular transmitter
and the counter value that was just decrypted are
within a formatted window of say 16, the counter is
stored and the command is executed. If the counter
value was not within the single operation window, but is
within the double operation window of say 32K window,
the transmitted synchronization value is stored in temporary location and it goes back to waiting for another
transmission. When the next valid transmission is
received, it will check the new value with the one in temporary storage. If the two values are sequential, it is
assumed that the counter had just gotten out of the single operation ‘window’, but is now back in sync, so the
new synchronization value is stored and the command
executed. If a transmitter has somehow gotten out of
the double operation window, the transmitter will not
work and must be re-learned. Since the entire window
rotates after each valid transmission, codes that have
been used are part of the ‘blocked’ (32K) codes and are
no longer valid. This eliminates the possibility of grabbing a previous code and re-transmitting to gain entry.
Note:
Yes
Decrypt Transmission
No
Is
Counter
Within 16
Entire Window
rotates to eliminate
use of previously
used codes
Yes
Execute
Command
and
Update
Counter
Blocked
(32K Codes)
Current
Position
Double
Operation
(32K Codes)
No
No
The synchronization method described in
this
section
is
only
typical
implementation and because it is usually
implemented in firmware, it can be altered
to fit the needs of a particular system
FIGURE 7-3: SYNCHRONIZATION WINDOW
Is
Decryption
Valid
Yes
No
Synchronization with Decoder
Is
Counter
Within 32K
Single Operation
Window (16 Codes)
Yes
Save Counter
in Temp Location
DS21137E-page 16
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 17 Monday, October 4, 1999 8:04 AM
HCS300
8.0
ELECTRICAL CHARACTERISTICS
TABLE 8-1:
ABSOLUTE MAXIMUM RATINGS
Symbol
Item
VDD
VIN
Note:
Rating
Units
Supply voltage
-0.3 to 6.6
Input voltage
-0.3 to VDD + 0.3
VOUT
Output voltage
-0.3 to VDD + 0.3
IOUT
Max output current
50
mA
TSTG
Storage temperature
-55 to +125
C (Note)
TLSOL
Lead soldering temp
300
C (Note)
VESD
ESD rating
4000
Stresses above those listed under “ABSOLUTE MAXIMUM RATINGS” may cause permanent damage to
the device.
TABLE 8-2:
DC CHARACTERISTICS
Commercial
Industrial
(C):
(I):
Tamb = 0°C to +70°C
Tamb = -40°C to +85°C
2.0V < VDD < 3.0
Parameter
Operating current (avg)2
Sym.
Min.
ICC
3.0 < VDD < 6.3
Typ.1
Max.
0.2
Min.
Typ.1
Max.
1.0
2.5
Unit
mA VDD = 3.0V
mA VDD = 6.3V
Standby current
ICCS
0.1
1.0
0.1
1.0
µA
Auto-shutoff
current3,4
ICCS
40
75
160
650
µA
High level Input
voltage
VIH
0.55VDD
VDD+0.
0.55VDD
VDD+0.
Low level input
voltage
VIL
-0.3
0.15VDD
-0.3
0.15VDD
High level output
voltage
VOH
0.7Vdd
Low level output
voltage
VOL
LED sink
current5
ILED
0.7Vdd
0.08VDD
0.08VDD
1.0
1.8
Conditions
IOH = -1.0 mA VDD = 2.0V
IOH = -2.0 mA VDD = 6.3V
IOL = 1.0 mA VDD = 2.0V
IOL = 2.0 mA VDD = 6.3V
2.0
2.7
3.7
mA VLED = 1.5V VDD = 3.0V
mA VLED = 1.5V VDD = 6.3V
2.5
Resistance; S0S3
RSO-3
40
60
80
40
60
80
kΩ
VDD = 4.0V
Resistance;
PWM
RPWM
80
120
160
80
120
160
kΩ
VDD = 4.0V
Note 1:
2:
3:
4:
5:
6:
Typical values are at 25°C.
No load.
Auto-shutoff current specification does not include the current through the input pulldown resistors.
Auto-shutoff current is periodically sampled and not 100% tested.
With VLOW Sel = 0 for operation from 2.0V to 3.0V and VLOW Sel = 1 for operation from 3.0V to 6.3V.
VLED is the voltage drop across the terminals of the LED.
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 17
21137e.Book Page 18 Monday, October 4, 1999 8:04 AM
HCS300
FIGURE 8-1: POWER UP AND TRANSMIT TIMING
Button Press
Detect
Code Word Transmission
TBP
TTD
TDB
Code
Word
PWM
Code
Word
Code
Word
Code
Word
TTO
Sn
TABLE 8-3:
POWER UP AND TRANSMIT TIMING REQUIREMENTS
VDD = +2.0 to 6.3V
Commercial (C): Tamb = 0°C to +70°C
Industrial
(I): Tamb = -40°C to +85°C
Parameter
Symbol
Min.
Max.
Unit
Remarks
TBP
10 + Code
Word Time
26 + Code
Word Time
ms
(Note 1)
Transmit delay from button detect
TTD
10
26
ms
Debounce delay
TDB
13
ms
Auto-shutoff time-out period
TTO
20
35
Time to second button press
(Note 2)
Note 1: TBP is the time in which a second button can be pressed without completion of the first code word and the
intention was to press the combination of buttons.
2: The auto shutoff timeout period is not tested.
FIGURE 8-2: PWM FORMAT
TE TE TE
LOGIC ‘0’
LOGIC ‘1’
TBP
Preamble
TP
Header
TH
Encrypted Portion
of Transmission
THOP
Fixed portion of
Transmission
TFIX
Guard
Time
TG
FIGURE 8-3: PREAMBLE/HEADER FORMAT
Preamble
P1
Header
P12
Bit 0 Bit 1
10 TE
23 TE
DS21137E-page 18
Data Word
Transmission
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 19 Monday, October 4, 1999 8:04 AM
HCS300
FIGURE 8-4: DATA WORD FORMAT
Serial Number
LSB
MSB LSB
Bit 0 Bit 1
Header
MSB
S3
S0
S1
Status
S2
VLOW RPT
Bit 30 Bit 31 Bit 32 Bit 33 Bit 58 Bit 59 Bit 60 Bit 61 Bit 62 Bit 63 Bit 64 Bit 65
Guard
Time
Fixed Code Word
Hopping Code Word
TABLE 8-4:
CODE WORD TRANSMISSION TIMING REQUIREMENTS
VDD = +2.0 to 6.0V
Commercial(C):Tamb = 0°C to +70°C
Industrial(I):Tamb = -40°C to +85°C
Symbol
Button Code
Characteristic
Code Words Transmitted
All
Number
Min.
of TE
Typ.
1 out of 2
1 out of 4
Max.
Min.
Typ.
Max.
Min.
Typ.
Max. Units
TE
Basic pulse element
260
400
660
130
200
330
65
100
165
µs
TBP
PWM bit pulse width
780
1200
1980
390
600
990
195
300
495
µs
TP
Preamble duration
23
6.0
9.2
15.2
3.0
4.6
7.6
1.5
2.3
3.8
ms
TH
Header duration
10
2.6
4.0
6.6
1.3
2.0
3.3
0.7
1.0
1.7
ms
THOP
Hopping code duration
96
25.0
38.4
63.4
12.5
19.2
31.7
6.2
9.6
15.8
ms
TFIX
Fixed code duration
102
26.5
40.8
67.3
13.3
20.4
33.7
6.6
10.2
16.8
ms
TG
Guard Time
39
10.1
15.6
25.7
5.1
7.8
12.9
2.5
3.9
6.4
ms

Total Transmit Time
270
70.2
108.0
178.2
35.1
54.0
89.1
17.6
27.0
44.6
ms

PWM data rate

1282
833
505
2564
1667
1010
5128
3333
2020
bps
Note:
The timing parameters are not tested but derived from the oscillator clock.
FIGURE 8-5: HCS300 TE VS. TEMP
Typical
1.7
1.6
1.5
TE Max.
LEGEND
= 2.0
= 3.0
= 6.0
1.4
1.3
1.2
1.1
1.0
0.9
0.8
0.7
TE Min.
0.6
-50 -40 -30 -20 -10 0 10 20 30 40 50 60 70 80 90
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 19
21137e.Book Page 20 Monday, October 4, 1999 8:04 AM
HCS300
HCS300 PRODUCT IDENTIFICATION SYSTEM
To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office.
HCS300
/P
Package:
Temperature
Range:
Device:
P = Plastic DIP (300 mil Body), 8-lead
SN = Plastic SOIC (150 mil Body), 8-lead
Blank = 0°C to +70°C
I = –40°C to +85°C
HCS300 = Code Hopping Encoder
HCS300T = Code Hopping Encoder (Tape and Reel)
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) 786-7277.
The Microchip Worldwide Site (www.microchip.com)
Please specify which device, revision of silicon and Data Sheet (include Literature #) you are using.
New Customer Notification System
Register on our web site (www.microchip.com/cn) to receive the most current information on our products.
DS21137E-page 20
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 21 Monday, October 4, 1999 8:04 AM
HCS300
NOTES:
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 21
21137e.Book Page 22 Monday, October 4, 1999 8:04 AM
HCS300
NOTES:
DS21137E-page 22
Preliminary
 1999 Microchip Technology Inc.
21137e.Book Page 23 Monday, October 4, 1999 8:04 AM
HCS300
NOTES:
 1999 Microchip Technology Inc.
Preliminary
DS21137E-page 23
WORLDWIDE SALES AND SERVICE
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11/15/99
Microchip received QS-9000 quality system
certification for its worldwide headquarters,
design and wafer fabrication facilities in
Chandler and Tempe, Arizona in July 1999. The
Company’s quality system processes and
procedures are QS-9000 compliant for its
PICmicro® 8-bit MCUs, KEELOQ® code hopping
devices, Serial EEPROMs and microperipheral
products. In addition, Microchip’s quality
system for the design and manufacture of
development systems is ISO 9001 certified.
All rights reserved. © 1999 Microchip Technology Incorporated. Printed in the USA. 11/99
Printed on recycled paper.
Information contained in this publication regarding device applications and the like is intended for suggestion only and may be superseded by updates. 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. The Microchip
logo and name are registered trademarks of Microchip Technology Inc. in the U.S.A. and other countries. All rights reserved. All other trademarks mentioned herein are the property of their respective companies.
 1999 Microchip Technology Inc.

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File Type                       : PDF
File Type Extension             : pdf
MIME Type                       : application/pdf
PDF Version                     : 1.3
Linearized                      : No
Create Date                     : 1999:10:04 08:06:19
Producer                        : Acrobat Distiller 3.01 for Windows
Title                           : Keeloq Code Hopping Encoder
Creator                         : FrameMaker 5.5.6p145
Subject                         : HCS300 Data Sheet
Author                          : Fanie Duvenhange
Keywords                        : HCS300, Code Hopping, Encoder
Modify Date                     : 1999:11:16 12:16:36-07:00
Page Count                      : 24
Page Mode                       : UseOutlines

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