HCS360-/P MICROCHIP [Microchip Technology], HCS360-/P Datasheet - Page 13

HCS360-/P

Manufacturer Part Number

HCS360-/P

Description

Manufacturer

MICROCHIP [Microchip Technology]

Datasheet

1.HCS360-P.pdf (28 pages)

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5.0

5.1

Code word completion is an automatic feature that

ensures that the entire code word is transmitted, even

if the button is released before the transmission is com-

plete and that a minimum of two words are completed.

The HCS360 encoder powers itself up when a button is

pushed and powers itself down after two complete

words are transmitted 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

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 extending the guard time

between transmissions. long guard time (LNGRD) is

used for reducing the average power of a transmission.

This is a selectable feature. Using the LNGRD allows

the user to transmit a higher amplitude transmission if

the transmission time per 100 ms is shorter. The FCC

puts constraints on the average power that can be

transmitted by a device, and LNGRD effectively

prevents continuous transmission by only allowing the

transmission of every second word. This reduces the

average power transmitted and hence, assists in FCC

approval of a transmitter device.

 2001 Microchip Technology Inc.

SPECIAL FEATURES

Code Word Completion

Long Guard Time

5.3

The CRC bits are calculated on the 65 previously trans-

mitted bits. The CRC bits can be used by the receiver

to check the data integrity before processing starts.

The CRC can detect all single bit and 66% of double bit

errors. The CRC is computed as follows:

EQUATION 5-1:

and

with

and

5.4

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 learning function. This can be done by utilizing

the seed value on the HCS360 which is stored in

EEPROM. Instead of the normal key generation method

being used to create the encryption key, this seed value

is used and there should not be any mathematical rela-

tionship between serial numbers and seeds for the best

security.

Note: The CRC may be wrong when the battery

the nth transmission bit 0 ≤ n ≤ 64

CRC 0 [ ]

Work around: If the CRC calculation is incor-

rect, recalculate for the opposite value of

CRC (Cycle Redundancy Check) Bits

Secure Learning

voltage is around either of the V

points. This may happen because V

sampled twice each transmission, once for

the CRC calculation (PWM is low) and once

when V

sion which could lead to a different value for

and the transmission

LOW

CRC 1 [ ]

tends to move slightly during a transmis-

being used for the CRC calculation

LOW

CRC 1 0 ,

(

CRC 0 [ ]

is transmitted (PWM is high).

CRC CALCULATION

[

CRC 0 [ ]

]

∧

HCS360

DS40152D-page 13

)

∧

CRC 1 [ ]

LOW

trip

HCS360-/P MICROCHIP [Microchip Technology], HCS360-/P Datasheet - Page 13

HCS360-/P

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