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Two Different IF Receiving Bandwidth Versions Are Available (BIF = 300 kHz or 600 kHz)
5 V to 20 V Automotive Compatible Data Interface
IC Condition Indicator, Sleep or Active Mode
Low Power Consumption Due to Configurable Self Polling with a Programmable
Timeframe Check
High Sensitivity, Especially at Low Data Rates
Data Clock Available for Manchester- and Bi-phase-coded Signals
Minimal External Circuitry Requirements, no RF Components on the PC Board Except
Matching to the Receiver Antenna
Sensitivity Reduction Possible Even While Receiving
Fully Integrated VCO
SO20 Package
Supply Voltage 4.5 V to 5.5 V, Operating Temperature Range -40°C to +105°C
Single-ended RF Input for Easy Adaptation to λ/4 Antenna or Printed Antenna on PCB
Low-cost Solution Due to High Integration Level
ESD Protection According to MIL-STD. 883 (4KV HBM)
High Image Frequency Suppression Due to 1 MHz IF in Conjunction with a SAW Frontend Filter. Up to 40 dB is Thereby Achievable With State-of-the-art SAWs.
Communication to Microcontroller Possible Via a Single, Bi-directional Data Line
Power Management (Polling) Is Also Possible by Means of a Separate Pin Via the
Microcontroller
Programmable Digital Noise Suppression
UHF ASK/FSK
Receiver
T5743
Preliminary
Description
The T5743 is a multi-chip PLL receiver device supplied in an SO20 package. It has
been especially developed for the demands of RF low-cost data transmission systems
with data rates from 1 kBaud to 10 kBaud in Manchester or Bi-phase code. The
receiver is well suited to operate with Atmel's PLL RF transmitter U2741B. Its main
applications are in the areas of telemetering, security technology and keyless-entry
systems. It can be used in the frequency receiving range of f0 = 300 MHz to 450 MHz
for ASK or FSK data transmission. All the statements made below refer to 433.92 MHz
and 315 MHz applications.
System Block Diagram
Figure 1. System Block Diagram
UHF ASK/FSK
Remote control receiver
UHF ASK/FSK
Remote control transmitter
T5743
U2741B
Demod.
XTO
Control
1...5
µC
PLL
IF Amp
Antenna
Antenna
VCO
Power
amp.
PLL
LNA
XTO
VCO
Rev. 4569A–RKE–12/02
1
Pin Configuration
Figure 2. Pinning SO20
SENS
1
20
DATA
IC_ACTIVE
2
19
POLLING/_ON
CDEM
3
18
DGND
AVCC
4
17
DATA_CLK
TEST
5
16
MODE
AGND
6
15
DVCC
MIXVCC
7
14
XTO
LNAGND
8
13
LFGND
LNA_IN
9
12
LF
n.c. 10
11
LFVCC
T5743
Pin Description
2
Pin
Symbol
1
SENS
2
IC_ACTIVE
3
CDEM
Lower cut-off frequency data filter
4
AVCC
Analog power supply
5
TEST
Test pin, during operation at GND
6
AGND
Analog ground
7
MIXVCC
8
LNAGND
9
LNA_IN
10
n.c.
11
LFVCC
12
LF
13
LFGND
14
XTO
Function
Sensitivity-control resistor
IC condition indicator
Low = sleep mode
High = active mode
Power supply mixer
High-frequency ground LNA and mixer
RF input
Not connected
Power supply VCO
Loop filter
Ground VCO
Crystal oscillator
T5743
4569A–RKE–12/02
T5743
Pin Description (Continued)
Pin
Symbol
15
DVCC
Digital power supply
16
MODE
Selecting 433.92 MHz/315 MHz
Low: fXT0 = 4.90625 MHz (USA)
High: fXT0 = 6.76438 MHz (Europe)
17
DATA_CLK
18
DGND
19
POLLING/_ON
20
DATA
Function
Bit clock of data stream
Digital ground
Selects polling or receiving mode
Low: receiving mode
High: polling mode
Data output/configuration input
Figure 3. Block Diagram
FSK/ASKDemodulator
and data filter
CDEM
RSSI
AVCC
Dem_out
Data
interface
DATA
Limiter out
POLLING/_ON
SENS
IF Amp
Sensitivity
reduction
Polling circuit
and
control logic
AGND
TEST
DATA_CLK
MODE
4. Order
DGND
FE
CLK
DVCC
IC_ACTIVE
LPF
3 MHz
MIXVCC
Standby logic
LFGND
LNAGND
LFVCC
IF Amp
LPF
3 MHz
VCO
XTO
XTO
f
LNA_IN
LNA
LF
64
3
4569A–RKE–12/02
RF Front-end
The RF front-end of the receiver is a heterodyne configuration that converts the input
signal into a 1 MHz IF signal. According to Figure 3, the front-end consists of an LNA
(low-noise amplifier), LO (local oscillator), a mixer and an RF amplifier.
The LO generates the carrier frequency for the mixer via a PLL synthesizer. The XTO
(crystal oscillator) generates the reference frequency fXTO. The VCO (voltage-controlled
oscillator) generates the drive voltage frequency fLO for the mixer. fLO is dependent on
the voltage at Pin LF. fLO is divided by factor 64. The divided frequency is compared to
fXTO by the phase frequency detector. The current output of the phase frequency detector is connected to a passive loop filter and thereby generates the control voltage VLF for
the VCO. By means of that configuration VLF is controlled in a way that fLO/64 is equal to
fXTO. If fLO is determined, fXTO can be calculated using the following formula: fXTO = fLO/64.
The XTO is a one-pin oscillator that operates at the series resonance of the quartz crystal. According to Figure 4, the crystal should be connected to GND via a capacitor CL.
The value of that capacitor is recommended by the crystal supplier. The value of CL
should be optimized for the individual board layout to achieve the exact value of fXTO and
hereby of fLO. When designing the system in terms of receiving bandwidth, the accuracy
of the crystal and the XTO must be considered.
Figure 4. PLL Peripherals
VS
DVCC
CL
XTO
R1 = 820 W
C9 = 4.7 nF
C10 = 1 nF
LFGND
LF
LFVCC
VS
R1
C10
C9
The passive loop filter connected to Pin LF is designed for a loop bandwidth of
BLoop = 100 kHz. This value for BLoop exhibits the best possible noise performance of
the LO. Figure 4 shows the appropriate loop filter components to achieve the desired
loop bandwidth. If the filter components are changed for any reason please notify that
the maximum capacitive load at Pin LF is limited. If the capacitive load is exceeded, a bit
check may no longer be possible since fLO cannot settle in time before the bit check
starts to evaluate the incoming data stream. Self polling does therefore also not work in
that case.
fLO is determined by the RF input frequency fRF and the IF frequency fIF using the following formula: fLO = fRF - fIF
To determine fLO, the construction of the IF filter must be considered at this point. The
nominal IF frequency is fIF = 1 MHz. To achieve a good accuracy of the filter’s corner frequencies, the filter is tuned by the crystal frequency fXTO. This means that there is a
fixed relation between fIF and fLO. This relation is dependent on the logic level at Pin
MODE.
4
T5743
4569A–RKE–12/02
T5743
This is described by the following formulas:
f LO
MODE = 0 (USA) : f IF = ---------314
f LO
MODE = 1 (Europe) : f IF = -----------------432.92
The relation is designed to achieve the nominal IF frequency of fIF = 1 MHz for most
applications. For applications where fRF = 315 MHz, MODE must be set to ‘0’. In the
case of fRF = 433.92 MHz, MODE must be set to ‘1’. For other RF frequencies, fIF is
not equal to 1 MHz. fIF is then dependent on the logical level at Pin MODE and on fRF.
Table 1 summarizes the different conditions.
The RF input either from an antenna or from a generator must be transformed to the RF
input Pin LNA_IN. The input impedance of that pin is provided in the electrical parameters. The parasitic board inductances and capacitances also influence the input
matching. The RF receiver T5743 exhibits its highest sensitivity at the best signal-tonoise ratio in the LNA. Hence, noise matching is the best choice for designing the transformation network.
A good practice when designing the network is to start with power matching. From that
starting point, the values of the components can be varied to some extent to achieve the
best sensitivity.
If a SAW is implemented into the input network a mirror frequency suppression of
DP Ref = 40 dB can be achieved. There are SAWs available that exhibit a notch at
Df = 2 MHz. These SAWs work best for an intermediate frequency of fIF = 1 MHz. The
selectivity of the receiver is also improved by using a SAW. In typical automotive applications, a SAW is used.
Figure 5 shows a typical input matching network, for f RF = 315 MHz and f R F =
433.92 MHz using a SAW. Figure 6 illustrates an according input matching to 50 W
without a SAW. The input matching networks shown in Figure 6 are the reference networks for the parameters given in the electrical characteristics.
Table 1. Calculation of LO and IF Frequency
Conditions
Local Oscillator Frequency
Intermediate Frequency
fRF = 315 MHz, MODE = 0
fLO = 314 MHz
fIF = 1 MHz
fRF = 433.92 MHz, MODE = 1
fLO = 432.92 MHz
fIF = 1 MHz
300 MHz < fRF < 365 MHz,
MODE = 0
365 MHz < fRF < 450 MHz,
MODE = 1
f RF
f LO = ------------------1
1 + ---------314
f LO
f IF = ---------314
f RF
f LO = ---------------------------1
1 + -----------------432.92
f LO
f IF = -----------------432.92
5
4569A–RKE–12/02
Figure 5. Input Matching Network with SAW Filter
8
8
LNAGND
LNAGND
T5743
9
C3
L
22p
25n
C16
33n
C2
1
OUT
OUT_GND
IN_GND
CASE_GND
3,4 7,8
8.2p
47p
25n
LNA_IN
C16
100p
TOKO LL2012
F27NJ
B3555
IN
2
L
8.2p
L3
27n
L2
TOKO LL2012
F33NJ
9
C3
C17
100p
fRF = 433.92 MHz
RFIN
T5743
LNA_IN
5
fRF = 315 MHz
6
82n
C2
L3
47n
L2
TOKO LL2012
F82NJ
RFIN
C17
1
2
10p
B3551
IN
22p
TOKO LL2012
F47NJ
OUT
OUT_GND
IN_GND
CASE_GND
3,4 7,8
5
6
Figure 6. Input Matching Network without SAW Filter
fRF = 433.92 MHz
8
LNAGND
fRF = 315 MHz
8
T5743
9
25n
15p
RFIN
9
LNA_IN
25n
33p
LNAGND
T5743
LNA_IN
RFIN
3.3p
100p
22n
TOKO LL2012
F22NJ
3.3p
100p
39n
TOKO LL2012
F39NJ
Please notify that for all coupling conditions (see Figure 5 and Figure 6), the bond wire
inductivity of the LNA ground is compensated. C3 forms a series resonance circuit
together with the bond wire. L = 25 nH is a feed inductor to establish a DC path. Its
value is not critical but must be large enough not to detune the series resonance circuit.
For cost reduction this inductor can be easily printed on the PCB. This configuration
improves the sensitivity of the receiver by about 1 dB to 2 dB.
6
T5743
4569A–RKE–12/02
T5743
Analog Signal Processing
IF Amplifier
The signals coming from the RF front-end are filtered by the fully integrated 4th-order IF
filter. The IF center frequency is fIF = 1 MHz for applications where fRF = 315 MHz or
fRF = 433.92 MHz is used. For other RF input frequencies refer to Table 1 to determine
the center frequency.
The T5743 is available with two different IF bandwidths. T5743P3, the version with
BIF = 300 kHz, is well suited for ASK systems where Atmel’s PLL transmitter U2741B is
used. The receiver T5743P6 employs an IF bandwidth of BIF = 600 kHz. Both versions
can be used together with the U2741B in ASK and FSK mode. If used in ASK applications, it allows higher tolerances for the receiver and PLL transmitter crystals. SAW
transmitters exhibit much higher transmit freqeuncy tolerances compared to PLL transmitters. Generally, it is necessary to use BIF = 600 kHz together with such transmitters.
RSSI Amplifier
The subsequent RSSI amplifier enhances the output signal of the IF amplifier before it is
fed into the demodulator. The dynamic range of this amplifier is DRRSSI = 60 dB. If the
RSSI amplifier is operated within its linear range, the best S/N ratio is maintained in ASK
mode. If the dynamic range is exceeded by the transmitter signal, the S/N ratio is
defined by the ratio of the maximum RSSI output voltage and the RSSI output voltage
due to a disturber. The dynamic range of the RSSI amplifier is exceeded if the RF input
signal is about 60 dB higher compared to the RF input signal at full sensitivity.
In FSK mode the S/N ratio is not affected by the dynamic range of the RSSI amplifier.
The output voltage of the RSSI amplifier is internally compared to a threshold voltage
VTh_red. VTh_red is determined by the value of the external resistor RSens. RSens is connected between Pin SENS and GND or VS. The output of the comparator is fed into the
digital control logic. By this means it is possible to operate the receiver at a lower
sensitivity.
If RSens is connected to GND, the receiver operates at full sensitivity.
If RSens is connected to VS, the receiver operates at a lower sensitivity. The reduced sensitivity is defined by the value of RSens, the maximum sensitivity by the signal-to-noise
ratio of the LNA input. The reduced sensitivity depends on the signal strength at the output of the RSSI amplifier.
Since different RF input networks may exhibit slightly different values for the LNA gain,
the sensitivity values given in the electrical characteristics refer to a specific input
matching. This matching is illustrated in Figure 6 and exhibits the best possible
sensitivity.
R Sens can be connected to V S or GND via a microcontroller. The receiver can be
switched from full sensitivity to reduced sensitivity or vice versa at any time. In polling
mode, the receiver will not wake up if the RF input signal does not exceed the selected
sensitivity. If the receiver is already active, the data stream at Pin DATA will disappear
when the input signal is lower than defined by the reduced sensitivity. Instead of the
data stream, the pattern according to Figure 7 is issued at Pin DATA to indicate that the
receiver is still active (see also figure 34).
Figure 7. Steady L State Limited DATA Output Pattern
DATA
t DATA_min
t DATA_L_max
7
4569A–RKE–12/02
FSK/ASK Demodulator
and Data Filter
The signal coming from the RSSI amplifier is converted into the raw data signal by the
ASK/FSK demodulator. The operating mode of the demodulator is set via the bit
ASK/_FSK in the OPMODE register. Logic ‘L’ sets the demodulator to FSK, applying ‘H’
to ASK mode.
In ASK mode, an automatic threshold control circuit (ATC) is used to set the detection
reference voltage to a value where a good signal-to-noise ratio is achieved. This circuit
effectively suppresses any kind of inband noise signals or competing transmitters. If the
S/N (ratio to suppress inband noise signals) exceeds 10 dB, the data signal can be
detected properly.
The FSK demodulator is intended to be used for an FSK deviation of 10 kHz £ Df £
100 kHz. In FSK mode the data signal can be detected if the S/N (ratio to suppress
inband noise signals) exceeds 2 dB. This value is guaranteed for all modulation
schemes of a disturber signal.
The output signal of the demodulator is filtered by the data filter before it is fed into the
digital signal processing circuit. The data filter improves the S/N ratio as its passband
can be adopted to the characteristics of the data signal. The data filter consists of a
1st-order highpass and a 2nd-order lowpass filter.
The highpass filter cut-off frequency is defined by an external capacitor connected to Pin
CDEM. The cut-off frequency of the highpass filter is defined by the following formula:
1
fcu_DF = ----------------------------------------------------------2 ´ p ´ 30 kW ´ CDEM
In self-polling mode, the data filter must settle very rapidly to achieve a low current consumption. Therefore, CDEM cannot be increased to very high values if self-polling is
used. On the other hand, CDEM must be large enough to meet the data filter requirements according to the data signal. Recommended values for CDEM are given in the
electrical characteristics.
The cut-off frequency of the lowpass filter is defined by the selected baud-rate range
(BR_Range). The BR_Range is defined in the OPMODE register (refer to section ‘Configuration of the Receiver’). The BR_Range must be set in accordance to the used baud
rate.
The T5743 is designed to operate with data coding where the DC level of the data signal
is 50%. This is valid for Manchester and Bi-phase coding. If other modulation schemes
are used, the DC level should always remain within the range of V DC_min = 33% and
VDC_max = 66%. The sensitivity may be reduced by up to 2 dB in that condition.
Each BR_Range is also defined by a minimum and a maximum edge-to-edge time
(tee_sig). These limits are defined in the electrical characteristics. They should not be
exceeded to maintain full sensitivity of the receiver.
Receiving
Characteristics
8
The RF receiver T5743 can be operated with and without a SAW front-end filter. In a
typical automotive application, a SAW filter is used to achieve better selectivity. The
selectivity with and without a SAW front-end filter is illustrated in Figure 8. This example
relates to ASK mode and the 300-kHz bandwidth version of the T5743. FSK mode and
the 600-kHz bandwidth version of the receiver exhibits similar behavior. Note that the
mirror frequency is reduced by 40 dB. The plots are printed relatively to the maximum
sensitivity. If a SAW filter is used, an insertion loss of about 4 dB must be considered.
T5743
4569A–RKE–12/02
T5743
Figure 8. Receiving Frequency Response
0.0
-10.0
without SAW
-20.0
-30.0
dP (dB)
-40.0
-50.0
-60.0
-70.0
-80.0
with SAW
-90.0
-100.0
-6.0
-5.0
-4.0
-3.0
-2.0
-1.0
0.0
1.0
2.0
3.0
4.0
5.0
6.0
df (MHz)
When designing the system in terms of receiving bandwidth, the LO deviation must be
considered as it also determines the IF center frequency. The total LO deviation is calculated to be the sum of the deviation of the crystal and the XTO deviation of the T5743.
Low-cost crystals are specified to be within ±100 ppm. The XTO deviation of the T5743
is an additional deviation due to the XTO circuit. This deviation is specified to be
±30 ppm. If a crystal of ±100 ppm is used, the total deviation is ±130 ppm in that case.
Note that the receiving bandwidth and the IF-filter bandwidth are equivalent in ASK
mode but not in FSK mode.
Polling Circuit and
Control Logic
The receiver is designed to consume less than 1 mA while being sensitive to signals
from a corresponding transmitter. This is achieved via the polling circuit. This circuit
enables the signal path periodically for a short time. During this time the bit-check logic
verifies the presence of a valid transmitter signal. Only if a valid signal is detected the
receiver remains active and transfers the data to the connected microcontroller. If there
is no valid signal present the receiver is in sleep mode most of the time resulting in low
current consumption. This condition is called polling mode. A connected microcontroller
is disabled during that time.
All relevant parameters of the polling logic can be configured by the connected microcontroller. This flexibility enables the user to meet the specifications in terms of current
consumption, system response time, data rate etc.
Regarding the number of connection wires to the microcontroller, the receiver is very
flexible. It can be either operated by a single bi-directional line to save ports to the connected microcontroller or it can be operated by up to five uni-directional ports.
Basic Clock Cycle of the
Digital Circuitry
The complete timing of the digital circuitry and the analog filtering is derived from one
clock. According to Figure 9, this clock cycle TClk is derived from the crystal oscillator
(XTO) in combination with a divider. The division factor is controlled by the logical state
at Pin MODE. According to section “RF Front-end”, the frequency of the crystal oscillator
(fXTO) is defined by the RF input signal (fRFin) which also defines the operating frequency
of the local oscillator (fLO).
9
4569A–RKE–12/02
Figure 9. Generation of the Basic Clock Cycle
T
Clk
MODE
Divider
:14/:10
f
XTO
16
L : USA(:10)
H: Europe(:14)
DVCC
15
XTO
XTO
14
Pin MODE can now be set in accordance with the desired clock cycle TClk. TClk controls
the following application relevant parameters:
•
Timing of the polling circuit including bit check
•
Timing of the analog and digital signal processing
•
Timing of the register programming
•
Frequency of the reset marker
•
IF filter center frequency (fIF0)
Most applications are dominated by two transmission frequencies: fSend = 315 MHz is
mainly used in USA, fSend = 433.92 MHz in Europe. In order to ease the usage of all TClkdependent parameters on this electrical characteristics display three conditions for each
parameter.
•
Application USA (fXTO = 4.90625 MHz, MODE = L, TClk = 2.0383 µs)
•
Application Europe (fXTO = 6.76438 MHz, MODE = H, TClk = 2.0697 µs)
•
Other applications (TClk is dependent on fXTO and on the logical state of Pin MODE.
The electrical characteristic is given as a function of TClk).
The clock cycle of some function blocks depends on the selected baud-rate range
(BR_Range) which is defined in the OPMODE register. This clock cycle TXClk is defined
by the following formulas for further reference:
BR_Range = BR_Range0:
BR_Range1:
BR_Range2:
BR_Range3:
Polling Mode
10
TXClk = 8 ´ TClk
TXClk = 4 ´ TClk
TXClk = 2 ´ TClk
TXClk = 1 ´ TClk
According to Figure 10, the receiver stays in polling mode in a continuous cycle of three
different modes. In sleep mode the signal processing circuitry is disabled for the time
period TSleep while consuming low current of IS = ISoff. During the start-up period, TStartup,
all signal processing circuits are enabled and settled. In the following bit-check mode,
the incoming data stream is analyzed bit by bit contra a valid transmitter signal. If no
valid signal is present, the receiver is set back to sleep mode after the period TBit-check.
This period varies check by check as it is a statistical process. An average value for
TBit-check is given in the electrical characteristics. During TStartup and TBit-check the current
consumption is IS = ISon. The condition of the receiver is indicated on Pin IC_ACTIVE.
The average current consumption in polling mode is dependent on the duty cycle of the
active mode and can be calculated as:
T5743
4569A–RKE–12/02
T5743
I Soff ´ T Sleep + I Son ´ ( T Startup + T Bit-check )
I Spoll = -------------------------------------------------------------------------------------------------------------T Sleep + T Startup + T Bit-check
During TSleep and TStartup the receiver is not sensitive to a transmitter signal. To guarantee the reception of a transmitted command the transmitter must start the telegram with
an adequate preburst. The required length of the preburst depends on the polling
parameters TSleep, TStartup, TBit-check and the start-up time of a connected microcontroller
(TStart,µC). Thus, TBit-check depends on the actual bit rate and the number of bits (NBit-check)
to be tested.
The following formula indicates how to calculate the preburst length.
TPreburst ³ TSleep + TStartup + TBit-check + TStart_µC
Sleep Mode
The length of period TSleep is defined by the 5-bit word Sleep of the OPMODE register,
the extension factor XSleep (according to Table 9), and the basic clock cycle TClk. It is
calculated to be:
TSleep = Sleep ´ XSleep ´ 1024 ´ TClk
In US- and European applications, the maximum value of TSleep is about 60 ms if XSleep
is set to 1. The time resolution is about 2 ms in that case. The sleep time can be
extended to almost half a second by setting XSleep to 8. XSleep can be set to 8 by bit
XSleepStd to 1.
According to Table 8, the highest register value of sleep sets the receiver into a permanent sleep condition. The receiver remains in that condition until another value for Sleep
is programmed into the OPMODE register. This function is desirable where several
devices share a single data line and may also be used for microcontroller polling — via
Pin POLLING/_ON, the receiver can be switched on and off.
11
4569A–RKE–12/02
Figure 10. Polling Mode Flow Chart
Sleep mode:
All circuits for signal processing are
disabled. Only XTO and Polling logic is
enabled.
Output level on Pin IC_ACTIVE => low
IS = ISoff
TSleep = Sleep ´ XSleep ´ 1024 TClk
Clk
Sleep:
Sleep:
XSleep:
XSleep:
::
TTClk
Clk
Start-up mode:
The signal processing circuits are
))
enabled. After the start-up time (TStartup
Startup
all circuits are in stable
condition and ready to receive.
Output level on Pin IC_ACTIVE => high
IS = ISon
::
TTStartup
Startup
5-bit
5-bit word
word defined
defined by
by Sleep0
Sleep0 to
to
Sleep4
Sleep4 in
in OPMODE
OPMODE register
register
Extension
Extension factor
factor defined
defined by
by
according
XSleep
according to
to Table
Table 99
XSleepStd
Std
Basic
Basic clock
clock cycle
cycle defined
defined by
by ffXTO
XTO
and
and Pin
Pin MODE
MODE
Is
Is defined
defined by
by the
the selected
selected baud
baud rate
rate
range and TClk.
TClk. The
Thebaud-rate
baud-raterange
rangeisis
defined
defined by
by Baud0
Baud0 and
and Baud1
Baud1 in
in the
the
OPMODE
OPMODE register.
register.
TStartup
Bit-check mode:
The incomming data stream is
analyzed. If the timing indicates a valid
transmitter signal, the receiver is set to
receiving mode. Otherwise it is set to
Sleep mode.
Output level on Pin IC_ACTIVE => high
IS = ISon
TBit-check
NO
Bit-check
OK ?
YES
Receiving mode:
The receiver is turned on permanently
and passes the data stream to the
connected microcontroller.
mC.
It can be set to Sleep mode through an
OFF command via Pin DATA or
POLLING/_ON.
Output level on Pin IC_ACTIVE => high
IS = ISon
OFF command
12
TTBit-check
::
Bit-check
Depends
Depends on
on the
the result
result of
of the
the bit
bit check.
check.
depends
IfIf the
depends on
on the
the
the bit
bit check
check is
is ok,
ok, TTBit-check
Bit-check
number
)
and
on
number of
of bits
bits to
to be
be checked
checked (N
(NBit-check
)
and
on
Bit-check
the
the utilized
utilized data
data rate.
rate.
IfIf the
the bit
bit check
check fails,
fails, the
the average
average time
time period
period
for
for that
that check
check depends
depends on
on the
the selected
selected baudbaud.. The
rate
The baud-rate
baud-rate range
range is
is
rate range
range and
and on
on TTClk
Clk
defined
defined by
by Baud0
Baud0 and
and Baud1
Baud1 in
in the
the OPMODE
OPMODE register
register
T5743
4569A–RKE–12/02
T5743
Figure 11. Timing Diagram for Complete Successful Bit Check
( Number of checked Bits: 3 )
Bit check ok
IC_ACTIVE
Bit check
1/2 Bit
1/2 Bit
1/2 Bit
1/2 Bit
1/2 Bit
1/2 Bit
Dem_out
Data_out (DATA)
TStart-up
T Bit-check
Start-up mode
Bit-check mode
Receiving mode
Bit-check Mode
In bit-check mode the incoming data stream is examined to distinguish between a valid
signal from a corresponding transmitter and signals due to noise. This is done by subsequent time frame checks where the distances between two signal edges are
continuously compared to a programmable time window. The maximum count of this
edge-to-edge tests before the receiver switches to receiving mode is also
programmable.
Configuring the Bit Check
Assuming a modulation scheme that contains two edges per bit, two time frame checks
are verifying one bit. This is valid for Manchester, Bi-phase and most other modulation
schemes. The maximum count of bits to be checked can be set to 0, 3, 6 or 9 bits via the
variable NBit-check in the OPMODE register. This implies 0, 6, 12 and 18 edge to edge
checks respectively. If NBit-check is set to a higher value, the receiver is less likely to
switch to receiving mode due to noise. In the presence of a valid transmitter signal, the
bit check takes less time if NBit–check is set to a lower value. In polling mode, the bit-check
time is not dependent on NBit-check. Figure 11 shows an example where 3 bits are tested
successfully and the data signal is transferred to Pin DATA.
According to Figure 12, the time window for the bit check is defined by two separate
time limits. If the edge-to-edge time tee is in between the lower bit-check limit TLim_min and
the upper bit-check limit TLim_max, the check will be continued. If tee is smaller than
T Lim_min or t ee exceeds T Lim_max , the bit check will be terminated and the receiver
switches to sleep mode.
Figure 12. Valid Time Window for Bit Check
1/fSig
Dem_out
tee
TLim_min
TLim_max
For best noise immunity it is recommended to use a low span between TLim_min and
TLim_max. This is achieved using a fixed frequency at a 50% duty cycle for the transmitter
preburst. A “11111...” or a “10101...” sequence in Manchester or Bi-phase is a good
choice concerning that advice. A good compromise between receiver sensitivity and
susceptibility to noise is a time window of ±25% regarding the expected edge-to-edge
time tee. Using pre-burst patterns that contain various edge-to-edge time periods, the
bit-check limits must be programmed according to the required span.
The bit-check limits are determined by means of the formula below.
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4569A–RKE–12/02
TLim_min = Lim_min ´ TXClk
TLim_max = (Lim_max –1) ´ TXClk
Lim_min and Lim_max are defined by a 5-bit word each within the LIMIT register.
Using above formulas, Lim_min and Lim_max can be determined according to the
required TLim_min, TLim_max and TXClk. The time resolution defining TLim_min and TLim_max is
TXClk. The minimum edge-to-edge time tee (tDATA_L_min, tDATA_H_min) is defined according
to the section ‘Receiving Mode’. The lower limit should be set to Lim_min ³ 10. The
maximum value of the upper limit is Lim_max = 63.
If the calculated value for Lim_min is < 19, it is recommended to check 6 or 9 bits
(NBit-check) to prevent switching to receiving mode due to noise.
Figure 13, Figure 14 and Figure 15 illustrate the bit check for the bit-check limits
Lim_min = 14 and Lim_max = 24. When the IC is enabled, the signal processing circuits
are enabled during TStartup. The output of the ASK/FSK demodulator (Dem_out) is undefined during that period. When the bit check becomes active, the bit-check counter is
clocked with the cycle TXClk.
Figure 13 shows how the bit check proceeds if the bit-check counter value CV_Lim is
within the limits defined by Lim_min and Lim_max at the occurrence of a signal edge. In
Figure 14 the bit check fails as the value CV_lim is lower than the limit Lim_min. The bit
check also fails if CV_Lim reaches Lim_max. This is illustrated in Figure 15.
Figure 13. Timing Diagram During Bit Check
( Lim_min = 14, Lim_max = 24 )
Bit check ok
Bit check ok
IC_ACTIVE
Bit check
1/2 Bit
1/2 Bit
1/2 Bit
Dem_out
Bit-checkcounter
0
TStart-up
1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 1 2 3 4
TXClk
TBit-check
Start-up mode
Bit-check mode
Figure 14. Timing Diagram for Failed Bit Check (Condition: CV_Lim < Lim_min)
( Lim_min = 14, Lim_max = 24 )
Bit check failed ( CV_Lim < Lim_min )
IC_ACTIVE
Bit check
1/2 Bit
Dem_out
Bit-checkcounter
14
0
1 2 3 4 5 6 1 2 3 4 5 6 7 8 9 10 11 12
0
TStart-up
TBit-check
TSleep
Start-up mode
Bit-check mode
Sleep mode
T5743
4569A–RKE–12/02
T5743
Figure 15. Timing Diagram for Failed Bit Check (Condition: CV_Lim ³ Lim_max)
( Lim_min = 14, Lim_max = 24 )
Bit check failed ( CV_Lim >= Lim_max )
IC_ACTIVE
Bit check
1/2 Bit
Dem_out
Bit-checkcounter
0
1 2 3 4 5 6 7 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
0
TStart-up
TBit-check
TSleep
Start-up mode
Bit-check mode
Sleep mode
Duration of the Bit Check
If no transmitter signal is present during the bit check, the output of the ASK/FSK
demodulator delivers random signals. The bit check is a statistical process and TBit-check
varies for each check. Therefore, an average value for TBit-check is given in the electrical
characteristics. TBit-check depends on the selected baud-rate range and on TClk. A higher
baud-rate range causes a lower value for TBit-check resulting in a lower current consumption in polling mode.
In the presence of a valid transmitter signal, TBit-check is dependent on the frequency of
that signal, fSig, and the count of the checked bits, NBit-check. A higher value for NBit-check
thereby results in a longer period for TBit-check requiring a higher value for the transmitter
pre-burst TPreburst.
Receiving Mode
If the bit check was successful for all bits specified by NBit-check, the receiver switches to
receiving mode. According to Figure 11, the internal data signal is switched to Pin DATA
in that case and the data clock is available after the start bit has been detected (Figure
22). A connected microcontroller can be woken up by the negative edge at Pin DATA or
by the data clock at Pin DATA_CLK. The receiver stays in that condition until it is
switched back to polling mode explicitly.
Digital Signal Processing
The data from the ASK/FSK demodulator (Dem_out) is digitally processed in different
ways and as a result converted into the output signal data. This processing depends on
the selected baud-rate range (BR_Range). Figure 16 illustrates how Dem_out is synchronized by the extended clock cycle TXClk. This clock is also used for the bit-check
counter. Data can change its state only after TXClk has elapsed. The edge-to-edge time
period tee of the Data signal as a result is always an integral multiple of TXClk.
The minimum time period between two edges of the data signal is limited to t ee ³
TDATA_min . This implies an efficient suppression of spikes at the DATA output. At the
same time it limits the maximum frequency of edges at DATA. This eases the interrupt
handling of a connected microcontroller.
The maximum time period for DATA to stay Low is limited to TDATA_L_max. This function is
employed to ensure a finite response time in programming or switching off the receiver
via Pin DATA. TDATA_L_max is thereby longer than the maximum time period indicated by
the transmitter data stream. Figure 18 gives an example where Dem_out remains Low
after the receiver has switched to receiving mode.
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4569A–RKE–12/02
Figure 16. Synchronization of the Demodulator Output
T XClk
Clock bit-check
counter
Dem_out
Data_out (DATA)
t ee
Figure 17. Debouncing of the Demodulator Output
Dem_out
Data_out (DATA)
t DATA_min
tDATA_min
tee
t DATA_min
t ee
t ee
Figure 18. Steady L State Limited DATA Output Pattern After Transmission
IC_ACTIVE
Bit check
Dem_out
Data_out (DATA)
tDATA_min
Start-up mode
Bit-check mode
tDATA_L_max
Receiving mode
After the end of a data transmission, the receiver remains active. Depending on the bit
Noise_Disable in the OPMODE register, the output signal at Pin DATA is high or random noise pulses appear at Pin DATA (see section “Digital Noise Supression”). The
edge-to-edge time period tee of the majority of these noise pulses is equal or slightly
higher than TDATA_min.
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4569A–RKE–12/02
T5743
Switching the Receiver Back
to Sleep Mode
The receiver can be set back to polling mode via Pin DATA or via Pin POLLING/_ON.
When using Pin DATA, this pin must be pulled to Low for the period t1 by the connected
microcontroller. Figure 19 illustrates the timing of the OFF command (see also Figure
34). The minimum value of t1 depends on BR_Range. The maximum value for t1 is not
limited but it is recommended not to exceed the specified value to prevent erasing the
reset marker. Note also that an internal reset for the OPMODE and the LIMIT register
will be generated if t1 exceeds the specified values. This item is explained in more detail
in the section “Configuration of the Receiver”. Setting the receiver to sleep mode via
DATA is achieved by programming bit 1 to be “1” during the register configuration. Only
one sync pulse (t3) is issued.
The duration of the OFF command is determined by the sum of t1, t2 and t10. After the
OFF command the sleep time TSleep elapses. Note that the capacitive load at Pin DATA
is limited (see section “Data Interface”).
Figure 19. Timing Diagram of the OFF-command via Pin DATA
IC_ACTIVE
IC_ACTIVE
t1
t1
t1
t2
t2
t2
t2
t3
t3
t3
t3
t5
t5
t5
t5
t4
t4
t4
t4
t10
t10
t10
t10
t7
t7
t7
t7
Out1
Out1
Out1
(mC)
(microcontroller)
(microcontroller)
(microcontroller
Data_out
Data_out (DATA)
(DATA)
X
X
X
Serial
Serial bi-directional
bi-directional
data
data line
line
X
X
X
Bit
Bit
Bit111
("1")
("1")
("1")
(Start
(Start
bit)
(Startbit)
bit)
TTTT
Sleep
Sleep
Sleep
Sleep
TTT
Start-up
Start-up
Start-up
T
Start-up
Sleep
Sleep
mode
Sleep
mode
Sleepmode
mode
Start-up
mode
Start-up
mode
Start-up
mode
Start-up
mode
OFF-command
OFF-command
OFF-command
Receiving
Receiving
mode
mode
Figure 20. Timing Diagram of the OFF-command via Pin POLLING/_ON
IC_ACTIVE
ton2
ton3
Bit check ok
POLLING/_ON
Data_out (DATA)
X
X
Serial bi-directional
data line
X
X
Receiving mode
Sleep mode
Start-up mode
Bit-check mode
Receiving mode
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4569A–RKE–12/02
Figure 21. Activating the Receiving Mode via Pin POLLING/_ON
IC_ACTIVE
t on1
POLLING/_ON
Data_out (DATA)
X
Serial bi-directional
data line
X
Sleep mode
Start-up mode
Receiving mode
Figure 20 illustrates how to set the receiver back to polling mode via Pin POLLING/_ON.
The Pin POLLING/_ON must be held to low for the time period ton2. After the positive
edge on Pin POLLING/_ON and the delay ton3, the polling mode is active and the sleep
time TSleep elapses.
This command is faster than using Pin DATA at the cost of an additional connection to
the microcontroller.
Figure 21 illustrates how to set the receiver to receiving mode via the Pin POLLING/_ON. The Pin POLLING/_ON must be held to Low. After the delay ton1 , the receiver
changes from sleep mode to start-up mode regardless the programmed values for TSleep
and NBit-check. As long as POLLING/_ON is held to Low, the values for TSleep and NBitcheck will be ignored, but not deleted (see also section “Digital Noise Suppression”).
If the receiver is polled exclusively by a microcontroller, TSleep must be programmed to
31 (permanent sleep mode). In this case the receiver remains in sleep mode as long as
POLLING/_ON is held to High.
Data Clock
The Pin DATA_CLK makes a data shift clock available to sample the data stream into a
shift register. Using this data clock, a microcontroller can easily synchronize the data
stream. This clock can only be used for Manchester and Bi-phase coded signals.
Generation of the data clock:
After a successful bit check, the receiver switches from polling mode to receiving mode
and the data stream is available at Pin DATA. In receiving mode, the data clock control
logic (Manchester/Bi-phase demodulator) is active and examines the incoming data
stream. This is done, like in the bit check, by subsequent time frame checks where the
distance between two edges is continuously compared to a programmable time window.
As illustrated in Figure 22, only two distances between two edges in Manchester and Biphase coded signals are valid (T and 2T).
The limits for T are the same as used for the bit check. They can be programmed in the
LIMIT-register (Lim_min and Lim_max, see Table 11 and Table 12).
The limits for 2T are calculated as follows:
Lower limit of 2T: Lim_min_2T =
(Lim_min + Lim_max) - (Lim_max - Lim_min)/2
Upper limit of 2T: Lim_max_2T=
(Lim_min + Lim_max) + (Lim_max - Lim_min)/2
(If the result for “Lim_min_2T” or “Lim_max_2T” is not an integer value, it will be round
up.)
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T5743
The data clock is available, after the data clock control logic has detected the distance
2T (Start bit) and is issued with the delay tDelay after the edge on Pin DATA (see figure
22).
If the data clock control logic detects a timing or logical error (Manchester code violation), like illustrated in Figure 23 and Figure 24, it stops the output of the data clock. The
receiver remains in receiving mode and starts with the bit check. If the bit check was
successful and the start bit has been detected, the data clock control logic starts again
with the generation of the data clock (see Figure 25).
It is recommended to use the function of the data clock only in conjunction with the bit
check 3, 6 or 9. If the bit check is set to 0 or the receiver is set to receiving mode via the
Pin POLLING/_ON, the data clock is available if the data clock control logic has
detected the distance 2T (Start bit).
Note that for Bi-phase-coded signals, the data clock is issued at the end of the bit.
Figure 22. Timing Diagram of the Data Clock
Preburst
Data
Bit check ok
T
'1'
'1'
'1'
'1'
2T
'1'
'0'
'1'
'1'
'0'
'1'
'0'
Dem_out
Data_out (DATA)
DATA_CLK
Start bit
tDelay
tP_Data_Clk
Receiving mode,
data clock control logic active
Bit-check mode
Figure 23. Data Clock Disappears Because of a Timing Error
Data
Timing error
(T ee < T Lim_min OR T Lim_max <T ee < T Lim_min_2T OR T ee > T Lim_max_2T)
T ee
'1'
'1'
'1'
'1'
'1'
'0'
'1'
'1'
'0'
'1'
'0'
Dem_out
Data_out (DATA)
DATA_CLK
Receiving mode,
data clock control
logic active
Receiving mode,
bit check active
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4569A–RKE–12/02
Figure 24. Data Clock Disappears Because of a Logical Error
Data
Logical error (Manchester code violation)
'1'
'1'
'1'
'0'
'1'
'1'
'?'
'0'
'0'
'1'
'0'
Dem_out
Data_out (DATA)
DATA_CLK
Receiving mode,
data clock control
logic active
Receiving mode,
bit check aktive
Figure 25. Output of the Data Clock After a Successful Bit Check
Data
Bit check ok
'1'
'1'
'1'
'1'
'1'
'0'
'1'
'1'
'0'
'1'
'0'
Dem_out
Data_out (DATA)
DATA_CLK
Receiving mode,
bit check active
Start bit
Receiving mode,
data clock control
logic active
The delay of the data clock is calculated as follows:
tDelay = tDelay1 + tDelay2
tDelay1 is the delay between the internal signals Data_Out and Data_In. For the rising
edge, tDelay1 depends on the capacitive load CL at Pin DATA and the external pull-up
resistor Rpup. For the falling edge, tDelay1 depends additionally on the external voltage VX
(see Figure 26, Figure 27 and Figure 34). When the level of Data_In is equal to the level
of Data_Out, the data clock is issued after an additional delay tDelay2.
Note that the capacitive load at Pin DATA is limited. If the maximum tolerated capacitive
load at Pin DATA is exceeded, the data clock disappears (see section “Data Interface”).
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4569A–RKE–12/02
T5743
Figure 26. Timing Characteristic of the Data Clock (Rising Edge on Pin DATA)
Data_Out
Serial bi-directional
data line
V
X
V Ih = 0,65 * V S
V Il = 0,35 * V S
Data_In
DATA_CLK
tDelay1
tDelay
tDelay2
tP_Data_Clk
Figure 27. Timing Characteristic of the Data Clock (Falling Edge of the Pin DATA)
Data_Out
VX
V Ih = 0,65 * V S
Serial bi-directional
data line
V Il = 0,35 * V S
Data_In
DATA_CLK
t Delay1
t Delay
t Delay2
tP_Data_Clk
Digital Noise
Suppression
After a data transmission, digital noise appears on the data output (see Figure 28). To
prevent that digital noise keeps the connected microcontroller busy, it can be suppressed in two different ways.
Automatic Noise Suppression
(see Figure 29)
If the bit Noise_Disable (Table 10) in the OPMODE register is set to 1 (default), the
receiver changes to bit-check mode at the end of a valid data stream. The digital noise
is suppressed and the level at Pin DATA is High in that case. The receiver changes
back to receiving mode, if the bit check was successful.
This way to suppress the noise is recommended if the data stream is Manchester or Biphase coded and is active after power on.
Figure 30 illustrates the behavior of the data output at the end of a data stream. Note
that if the last period of the data stream is a high period (rising edge to falling edge), a
pulse occurs on Pin DATA. The length of the pulse depends on the selected baud-rate
range.
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4569A–RKE–12/02
Figure 28. Output of Digital Noise at the End of the Data Stream
Bit
Bit check
check ok
ok
Bit check ok
Data_out (DATA)
Preburst
Data
Data
Digital
Digital Noise
Noise
Digital
Digital Noise
Noise
Preburst
Preburst
Data
Data
Digital
Digital Noise
Noise
DATA_CLK
Receiving mode,
data clock control
logic active
Bit-check
mode
Receiving
Receiving mode,
mode,
bit
bit check
check aktive
aktive
Receiving
Receiving mode,
mode,
data
data clock
clock control
control
logic
logic active
active
Receiving
Receiving mode,
mode,
bit
bit check
check aktive
aktive
Figure 29. Automatic Noise Suppression
Bit check ok
Data_out (DATA)
Bit check ok
Preburst
Data
Preburst
Data
DATA_CLK
Bit-check
mode
Receiving mode,
data clock control
logic active
Receiving mode,
data clock control
logic active
Bit-check
mode
Bit-check
mode
Figure 30. Occurence of a Pulse at the End of the Data Stream
(tee < TLim_min OR TLim_max < tee
Timing error
)
< TLim_min_2T OR tee > TLim_max_2T
T ee
Data stream
'1'
'1'
Digital noise
'1'
Dem_out
Data_out (DATA)
T Pulse
DATA_CLK
Receiving mode,
data clock control
logic active
Controlled Noise Suppression
by the Microcontroller (see
Figure 31)
Bit-check mode
If the bit Noise_Disable (see Table 10) in the OPMODE register is set to 0, digital noise
appears at the end of a valid data stream. To suppress the noise, the Pin POLLING/_ON must be set to Low. The receiver remains in receiving mode. Then, the OFFcommand causes the change to the start-up mode. The programmed sleep time (see
Table 8) will not be executed because the level at Pin POLLING/_ON is low, but the bit
check is active in that case. The OFF-command activates the bit check also if the Pin
POLLING/_ON is held to Low. The receiver changes back to receiving mode if the bit
check was successful. To activate the polling mode at the end of the data transmission,
the Pin POLLING/_ON must be set to High.
This way to suppress the noise is recommended if the data stream is not Manchester or
Bi-phase coded.
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T5743
Figure 31. Controlled Noise Suppression
Bit check ok
Serial bi-directional
data line
OFF-command
Preburst
Data
Bit check ok
Digital Noise
Preburst
Data
Digital Noise
(DATA_CLK)
POLLING/_ON
Bit-check
mode
Configuration of the
Receiver
Receiving mode
Start-up Bit-check
mode
mode
Receiving mode
Sleep
mode
The T5743 receiver is configured via two 12-bit RAM registers called OPMODE and
LIMIT. The registers can be programmed by means of the bidirectional DATA port. If the
register contents have changed due to a voltage drop, this condition is indicated by a
certain output pattern called reset marker (RM). The receiver must be reprogrammed in
that case. After a power-on reset (POR), the registers are set to default mode. If the
receiver is operated in default mode, there is no need to program the registers. Table 4
shows the structure of the registers. According to Table 2 bit 1 defines if the receiver is
set back to polling mode via the OFF-command (see section “Receiving Mode”) or if it is
programmed. Bit 2 represents the register address. It selects the appropriate register to
be programmed. To get a high programming reliability, Bit15 (Stop bit), at the end of the
programming operation, must be set to 0.
Table 2. Effect of Bit 1 and Bit 2 on Programming the Registers
Bit 1
Bit 2
1
x
The receiver is set back to polling mode (OFF command)
Action
0
1
The OPMODE register is programmed
0
0
The LIMIT register is programmed
Table 3. Effect of Bit 15 on Programming the Register
Bit 15
Action
0
The values will be written into the register (OPMODE or LIMIT)
1
The values will not be written into the register
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4569A–RKE–12/02
Table 4. Effect of the Configuration Words Within the Registers
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Bit 8
Bit 9
Bit 10
Bit 11
Bit 12
Bit 13
Bit 14
X
Sleep
Noise
Suppression
Bit 15
OFF-command
1
OPMODE register
BR_Range
0
Modulation
NBit-check
1
Default values
of Bit 3...14
Sleep
Baud1
Baud0
BitChk1
BitChk0
ASK/_
FSK
Sleep4
Sleep3
Sleep2
Sleep1
Sleep0
XSleepStd
Noise_
Disable
0
0
0
1
0
0
0
1
1
0
0
1
0
LIMIT register
Lim_min
0
0
Default values
of Bit 3...14
Lim_max
Lim_
min5
Lim_
min4
Lim_
min3
Lim_
min2
Lim_
min1
Lim_
min0
Lim_
max5
Lim_
max4
Lim_
max3
Lim_
max2
Lim_
max1
Lim_max0
0
1
0
1
0
1
1
0
1
0
0
1
0
Table 5 to Table 12 illustrate the effect of the individual configuration words. The default
configuration is highlighted for each word.
BR_Range sets the appropriate baud-rate range and simultaneously defines XLim.
XLim is used to define the bit-check limits TLim_min and TLim_max as shown in table 11 and
table 12.
Table 5. Effect of the Configuration Word BR_Range
BR_Range
Baud1
Baud0
Baud-Rate Range/Extension Factor for Bit-Check Limits (XLim)
0
0
BR_Range0 (application USA/Europe: BR_Range0 = 1.0 kBaud to
1.8 kBaud) XLim = 8 (default)
0
1
BR_Range1 (application USA/Europe: BR_Range1 = 1.8 kBaud to
3.2 kBaud) XLim = 4
1
0
BR_Range2 (application USA/Europe: BR_Range2 = 3.2 kBaud to
5.6 kBaud) XLim = 2
1
1
BR_Range3 (application USA/Europe: BR_Range3 = 5.6 kBaud to
10 kBaud) XLim = 1
Table 6. Effect of the Configuration Word NBit-check
NBit-check
24
BitChk1
BitChk0
Number of Bits to be Checked
0
0
0
0
1
3 (default)
1
0
6
1
1
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T5743
Table 7. Effect of the Configuration Bit Modulation
Modulation
Selected Modulation
ASK/_FSK
0
FSK (default)
1
ASK
Table 8. Effect of the Configuration Word Sleep
Sleep
Start Value for Sleep Counter
(TSleep = Sleep × Xsleep × 1024 × TClk)
Sleep4
Sleep3
Sleep2
Sleep1
Sleep0
0
0
0
0
0
0 (Receiver is continuously polling until a
valid signal occurs)
0
0
0
0
1
1 (TSleep » 2 ms for XSleep = 1 in US-/
European applications)
0
0
0
1
0
2
0
0
0
1
1
3
...
...
...
...
...
...
0
0
1
1
0
6 (USA: TSleep = 12.52 ms, Europe:
TSleep = 12.72 ms) (default)
...
...
...
...
...
...
1
1
1
0
1
29
1
1
1
1
0
30
1
1
1
1
1
31 (Permanent sleep mode)
Table 9. Effect of the Configuration Bit XSleep
XSleep
XSleepStd
Extension Factor for Sleep Time
(TSleep = Sleep × Xsleep × 1024 × TClk)
0
1 (default)
1
8
Table 10. Effect of the Configuration Bit Noise Suppression
Noise Suppression
Noise_Disable
Suppression of the Digital Noise at Pin DATA
0
Noise suppression is inactive
1
Noise suppression is active (default)
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4569A–RKE–12/02
Table 11. Effect of the Configuration Word Lim_min
Lim_min (1) (Lim_min < 10 Is Not Applicable)
Lower Limit Value for Bit Check
Lim_min5
Lim_min4
Lim_min3
Lim_min2
Lim_min1
Lim_min0
(TLim_min = Lim_min × Lim × TClk)
0
0
1
0
1
0
10
0
0
1
0
1
1
11
0
0
1
1
0
0
12
...
...
...
...
...
...
0
1
0
1
0
1
...
...
...
...
...
...
1
1
1
1
0
1
61
1
1
1
1
1
0
62
1
1
1
1
1
63
1
Note:
21 (default)
USA: TLim_min = 342 µs, Europe: TLim_min = 348 µs)
1. Lim_min is also be used to determine the margins of the data clock control logic (see section “Data Clock”).
Table 12. Effect of the Configuration Word Lim_max
Lim_max (1) (Lim_max < 12 Is Not Applicable)
Upper Limit Value for Bit Check
Lim_max5
Lim_max4
Lim_max3
Lim_max2
Lim_max1
Lim_max0
(TLim_max = (Lim_max - 1) × XLim × TClk)
0
0
1
1
0
0
12
0
0
1
1
0
1
13
0
0
1
1
1
0
14
...
...
...
...
...
...
1
0
1
0
0
1
...
...
...
...
...
...
1
1
1
1
0
1
61
1
1
1
1
1
0
62
1
1
1
1
1
63
1
Note:
41 (default)
USA: TLim_max = 652 ms,
Europe: TLim_max = 662 µs)
1. Lim_max is also be used to determine the margins of the data clock control logic (see section “Data Clock”).
Conservation of the Register
Information
The T5743 implies an integrated power-on reset and brown-out detection circuitry to
provide a mechanism to preserve the RAM register information.
According to Figure 32, a power-on reset (POR) is generated if the supply voltage VS
drops below the threshold voltage VThReset. The default parameters are programmed into
the configuration registers in that condition. Once VS exceeds VThReset the POR is cancelled after the minimum reset period tRst. A POR is also generated when the supply
voltage of the receiver is turned on.
To indicate that condition, the receiver displays a reset marker (RM) at Pin DATA after a
reset. The RM is represented by the fixed frequency fRM at a 50% duty-cycle. RM can be
cancelled via a Low pulse t1 at Pin DATA.
26
T5743
4569A–RKE–12/02
T5743
The RM implies the following characteristics:
•
fRM is lower than the lowest feasible frequency of a data signal. By this means, RM
cannot be misinterpreted by the connected microcontroller.
•
If the receiver is set back to polling mode via Pin DATA, RM cannot be cancelled by
accident if t1 is applied according to the proposal in the section “Programming the
Configuration Registers”.
By means of that mechanism the receiver cannot lose its register information without
communicating that condition via the reset marker RM.
Figure 32. Generation of the Power-on Reset
V ThReset
VS
POR
tRst
Data_out (DATA)
X
1 / f RM
Programming the Configuration Register
Figure 33. Timing of the Register Programming
IC_ACTIVE
t1
t2
t3
t9
t8
t5
t4
t6
t7
Out1 (µC)
Data_out (DATA)
X
Serial bi-directional
data line
X
Bit 1
("0")
(Start bit)
Bit 2
("1")
(Registerselect)
Programming frame
Receiving
mode
Bit 14
("0")
(Poll8)
Bit 15
("0")
(Stop bit)
TSleep TStart-up
SleepStart-up
mode mode
27
4569A–RKE–12/02
Figure 34. Data Interface
V X = 5 V toV20=V5 V to 20 V
V S = 4.5 VVto 5.5
V
S = 4.5 V to 5.5 V
0V/5V
Data_In
Rpup
0 ... 20 V
Input Interface Interface
0 V / Input
5V
Data_In
X
T5743 T5743
ID
DATA
0 ... 20 V
Microcontroller
Microcontroller
Rpup
I/O
DATA
I/O
Serial bi-directional data line
Serial bi-directional data line
ID
CL
CL
Out1 mîcrocontroller
Out1 mîcrocontroller
Data_out Data_out
The configuration registers are programmed serially via the bi-directional data line
according to Figure 33 and Figure 34.
To start programming, the serial data line DATA is pulled to Low for the time period t1 by
the microcontroller. When DATA has been released, the receiver becomes the master
device. When the programming delay period t2 has elapsed, it emits 15 subsequent
synchronization pulses with the pulse length t3. After each of these pulses, a programming window occurs. The delay until the program window starts is determined by t4, the
duration is defined by t5. Within the programming window, the individual bits are set. If
the microcontroller pulls down Pin DATA for the time period t7 during t5, the according
bit is set to “0”. If no programming pulse t7 is issued, this bit is set to “1”. All 15 bits are
subsequently programmed this way. The time frame to program a bit is defined by t6.
Bit 15 is followed by the equivalent time window t9. During this window, the equivalence
acknowledge pulse t8 (E_Ack) occurs if the just programmed mode word is equivalent to
the mode word that was already stored in that register. E_Ack should be used to verify
that the mode word was correctly transferred to the register. The register must be programmed twice in that case.
Programming of a register is possible both in sleep- and in active-mode of the receiver.
During programming, the LNA, LO, lowpass filter IF-amplifier and the FSK/ASK
Manchester demodulator are disabled.
The programming start pulse t1 initiates the programming of the configuration registers.
If bit 1 is set to “1”, it represents the OFF-command to set the receiver back to polling
mode at the same time. For the length of the programming start pulse t1, the following
convention should be considered:
•
t1(min) < t1 < 5632 ´ TClk: t1(min) is the minimum specified value for the relevant
BR_Range
Programming respectively OFF-command is initiated if the receiver is not in reset
mode.If the receiver is in reset mode, programming respectively Off-command is not initiated and the reset marker RM is still present at Pin DATA.
This period is generally used to switch the receiver to polling mode or to start the programming of a register. In reset condition, RM is not cancelled by accident.
•
28
t1 > 7936 ´ TClk
T5743
4569A–RKE–12/02
T5743
Programming respectively OFF-command is initiated in any case. The registers
OPMODE and LIMIT are set to the default values. RM is cancelled if present.
This period is used if the connected microcontroller detected RM. If the receiver operates in default mode, this time period for t1 can generally be used.
Note that the capacitive load at Pin DATA is limited.
Data Interface
The data interface (see Figure 34) is designed for automotive requirements. It can be
connected via the pull-up resistor Rpup up to 20 V and is short-circuit-protected.
The applicable pull-up resistor Rpup depends on the load capacity CL at Pin DATA and
the selected BR_range (see Table 13). More detailed information about the calculation
of the maximum load capacity at Pin DATA is given in the “Application Hints U3743BM”.
Table 13. Applicable Rpup
BR_range
Applicable Rpup
B0
1.6 kW to 47 kW
B1
1.6 kW to 22 kW
B2
1.6 kW to 12 kW
B3
1.6 kW to 5.6 kW
B0
1.6 kW to 470 kW
B1
1.6 kW to 220 kW
B2
1.6 kW to 120 kW
B3
1.6 kW to 56 kW
CL £ 1 nF
CL £ 100 pF
Figure 35. Application Circuit: fRF = 433.92 MHz without SAW Filter
VS
C7
2.2u
10%
IC_ACTIVE
C6
10n
10%
R2
Sensitivity reduction
56k to 150k
V X = 5 V to 20 V
GND
R3
>= 1.6k
T5743
1
2
3
C14
33n 5%
C13
10n
10%
C3
15p
5%
np0
4
5
6
SENS
DATA
IC_ACTIVE POLLING/_ON
CDEM
DGND
DATA_CLK
AVCC
MODE
TEST
AGND
DVCC
7
MIXVCC
8
9
10
LNAGND
LNA_IN
NC
C17
3.3p
5% np0
15
XTO 14
LFGND 13
LF 12
LFVCC 11
DATA
POLLING/_ON
DATA_CLK
Q1
6.7643MHz
C11
12p
2% np0
C12
C15
150p
10%
COAX
20
19
18
17
16
C16
100p
5% np0
L2 TOKO LL2012 F22NJ
22n
5%
10n
10%
C8
150p
10%
R1
820
5%
C9
4.7n
5%
C10
1n
5%
29
4569A–RKE–12/02
Figure 36. Application Circuit: fRF = 315 MHz without SAW Filter
VS
C7
2.2u
10%
IC_ACTIVE
C6
10n
10%
R2
Sensitivity reduction
56k to 150K
V X = 5 V to 20 V
GND
R3
>= 1.6k
T5743
1
2
3
C14
33n 5%
C13
10n
10%
C3
33p
5%
np0
4
5
6
SENS
DATA
IC_ACTIVE POLLING/_ON
CDEM
DGND
DATA_CLK
AVCC
MODE
TEST
AGND
DVCC
7
MIXVCC
8
9
10
LNAGND
LNA_IN
NC
C17
3.3p
5% np0
15
XTO 14
LFGND 13
LF 12
LFVCC 11
DATA
POLLING/_ON
DATA_CLK
Q1
C11
15p
2% np0
4.906MHz
C12
C15
150p
10%
COAX
20
19
18
17
16
10n
10%
C8
150p
10%
C16
R1
820
5%
100p
5% np0
L2 TOKO LL2012 F39NJ
39n
5%
C9
4.7n
5%
C10
1n
5%
Figure 37. Application Circuit: fRF = 433.92 MHz with SAW Filter
VS
C7
2.2u
10%
IC_ACTIVE
C6
10n
10%
R2
Sensitivity reduction
56k to 150k
V X = 5 V to 20 V
GND
R3
>= 1.6k
T5743
1
2
3
C14
33n 5%
C13
10n
10%
C3
22p
5%
np0
7
SENS
DATA
IC_ACTIVE POLLING/_ON
CDEM
DGND
DATA_CLK
AVCC
MODE
TEST
AGND
DVCC 15
MIXVCC
XTO 14
8
9
10
LNAGND
LNA_IN
NC
4
5
6
C16
100p
5%
np0
30
LFGND 13
LF 12
LFVCC 11
DATA
POLLING/_ON
DATA_CLK
Q1
6.7643MHz
C11
12p
2% np0
C12
C15
150p
10%
COAX
20
19
18
17
16
L2 TOKO LL2012
F33NJ
1
IN
2
IN_GND
33n
3
C2 5%
4
8.2p
CASE_GND
5%
np0
B3555
C17
8,2p
5% np0
L3 TOKO LL2012
F27 NJ
27n
5%
OUT
OUT_GND
5
6
CASE_GND
7
8
C8
150p
10%
10n
10%
R1
820
5%
C9
4.7n
5%
C10
1n
5%
T5743
4569A–RKE–12/02
T5743
Figure 38. Application Circuit: fRF = 315 MHz with SAW Filter
VS
C7
2.2u
10%
IC_ACTIVE
C6
10n
10%
R2
Sensitivity reduction
56k to 150k
V X = 5 V to 20 V
GND
R3
>= 1.6k
T5743
1
2
3
C14
33n 5%
C13
10n
10%
C3
47p
5%
np0
4
5
6
SENS
DATA
IC_ACTIVE POLLING/_ON
CDEM
DGND
DATA_CLK
AVCC
MODE
TEST
AGND
DVCC
7
MIXVCC
8
9
10
LNAGND
LNA_IN
NC
C16
100p
5%
np0
L2 TOKO LL2012
F82NJ
1
2
82n
3
C2 5%
4
10p
5%
np0
15
XTO 14
LFGND 13
LF 12
LFVCC 11
DATA
POLLING/_ON
DATA_CLK
Q1
4.906MHz
C11
15p
2% np0
C12
C15
150p
10%
COAX
20
19
18
17
16
IN
IN_GND
CASE_GND
22p
5% np0
L3 TOKO LL2012
F47NJ
47n
5%
OUT
OUT_GND
C8
150p
10%
10n
10%
C17
R1
820
5%
C9
4.7n
5%
5
6
7
CASE_GND 8
C10
1n
5%
B3551
Absolute Maximum Ratings
Parameters
Symbol
Min.
Max.
Unit
Supply voltage
VS
6
V
Power dissipation
Ptot
1000
mW
Junction temperature
Tj
150
°C
Storage temperature
Tstg
-55
+125
°C
Ambient temperature
Tamb
-40
+105
°C
10
dBm
Maximum input level, input matched to 50 W
Pin_max
Thermal Resistance
Parameters
Junction ambient
Symbol
Value
Unit
RthJA
100
K/W
31
4569A–RKE–12/02
Electrical Characteristics
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
6.76438 MHz Osc.
(MODE: 1)
Parameter
Test Conditions
Symbol
Min.
Typ.
Max.
4.90625 MHz Osc.
(MODE: 0)
Min.
Typ.
Variable Oscillator
Max.
Min.
2.0383
2.0383
16.3
8.2
4.1
2.0
Typ.
Max.
Unit
1/fXTO/10
1/fXTO/14
1/fXTO/10
1/fXTO/14
µs
µs
16.3
8.2
4.1
2.0
8 ´ TClk
4 ´ TClk
2 ´ TClk
1 ´ TClk
8 ´ TClk
4 ´ TClk
2 ´ TClk
1 ´ TClk
µs
µs
µs
µs
ms
Basic Clock Cycle of the Digital Circuitry
Basic clock
cycle
MODE = 0 (USA)
MODE = 1 (Europe)
TClk
Extended basic
clock cycle
BR_Range0
BR_Range1
BR_Range2
BR_Range3
2.0697
2.0697
TXClk
16.6
8.3
4.1
2.1
16.6
8.3
4.1
2.1
TSleep
Sleep ´
XSleep ´
1024 ´
2.0697
Sleep ´
XSleep ´
1024 ´
2.0697
Sleep ´
XSleep ´
1024 ´
2.0383
Sleep ´
XSleep ´
1024 ´
2.0383
Sleep ´
XSleep ´
1024 ´ TClk
Sleep ´
XSleep ´
1024 ´ TClk
1855
1061
1061
663
1855
1061
1061
663
1827
1045
1045
653
1827
1045
1045
653
896.5
512.5
512.5
320.5 ´ TClk
896.5
512.5
512.5
320.5 ´
TClk
Polling Mode
Sleep time (see Sleep and XSleep
Figure 10,
are defined in the
Figure 19, and OPMODE register
Figure 33)
Start-up time
(see Figure 10,
and Figure 11)
BR_Range0
BR_Range1
BR_Range2
BR_Range3
Time for bit
check (see
Figure 10)
Average bit-check
time while polling,
no RF applied
(see Figure 14, and
Figure 15)
BR_Range0
BR_Range1
BR_Range2
BR_Range3
Bit-check time for a
valid input signal fSig ,
(see Figure 11)
NBit-check = 0
NBit-check = 3
NBit-check = 6
NBit-check = 9
TStartup
0.45
0.24
0.14
0.08
TBit-check
TBit-check
3/fSig
6/fSig
9/fSig
ms
ms
ms
ms
0.45
0.24
0.14
0.08
3.5/fSig
6.5/fSig
9.5/fSig
3/fSig
6/fSig
9/fSig
µs
µs
µs
µs
3.5/fSig
6.5/fSig
9.5/fSig
1 X TXClk
3/fSig
6/fSig
9/fSig
1 ´ TClk
3.5/fSig
6.5/fSig
9.5/fSig
ms
ms
ms
ms
Receiving Mode
Intermediate
frequency
MODE = 0 (USA)
MODE = 1 (Europe)
Baud-rate
range
BR_Range0
BR_Range1
BR_Range2
BR_Range3
Minimum time
period between
edges at Pin
DATA
(see Figure 7,
Figure 17 and
Figure 18, with
the exception of
parameter
TPulse)
BR_Range =
32
BR_Range0
BR_Range1
BR_Range2
BR_Range3
fIF
BR_Range
tDATA-min
1.0
1.0
1.0
1.8
3.2
5.6
1.8
3.2
5.6
10.0
1.0
1.8
3.2
5.6
1.8
3.2
5.6
10.0
165
83
41.4
20.7
165
83
41.4
20.7
163
81
40.7
20.4
163
81
40.7
20.4
fXTO ´ 64/314
fXTO ´ 64/432.92
MHz
MHz
BR_Range0 ´ 2 ms/TClk
BR_Range1 ´ 2 ms/TClk
BR_Range2 ´ 2 ms/TClk
BR_Range3 ´ 2 ms/TClk
kBaud
kBaud
kBaud
kBaud
10 ´ TXClk
10 ´ TXClk
10 ´ TXClk
10 ´ TXClk
10 ´ TXClk
10 ´ TXClk
10 ´ TXClk
10 ´ TXClk
µs
µs
µs
µs
T5743
4569A–RKE–12/02
T5743
Electrical Characteristics (Continued)
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
6.76438 MHz Osc.
(MODE: 1)
Parameter
Test Conditions
Maximum Low
period at Pin
DATA (see
Figure 7 and
Figure 18)
BR_Range =
BR_Range0
BR_Range1
BR_Range2
BR_Range3
Symbol
tDATA_L_max
Min.
Typ.
4.90625 MHz Osc.
(MODE: 0)
Max.
Min.
Typ.
Max.
2152
1076
538
270
2152
1076
538
270
2120
1060
530
265
2120
1060
530
265
21.8
19.4
21.5
Variable Oscillator
Min.
130 ´ TXClk
130 ´ TXClk
130 ´ TXClk
130 ´ TXClk
Typ.
Max.
130 ´ TXClk
130 ´ TXClk
130 ´ TXClk
130 ´ TXClk
Unit
µs
µs
µs
µs
Delay to
activate the
start-up mode
(see Figure 21)
Ton1
19.7
OFF- command
at Pin
POLLING/_ON
(see Figure 20)
Ton2
16.6
Delay to
activate the
sleep mode
(see Figure 20)
Ton3
17.6
19.7
17.4
19.4
8.5 ´ TClk
9.5 ´ TClk
µs
16.6
8.3
4.1
2.1
16.6
8.3
4.1
2.1
16.3
8.2
4.1
2.0
16.3
8.2
4.1
2.0
8 ´ TClk
4 ´ TClk
2 ´ TClk
1 ´ TClk
8 ´ TClk
4 ´ TClk
2 ´ TClk
1 ´ TClk
µs
µs
µs
µs
fRM
117.9
117.9
119.8
119.8
1
------------------------------4096 ´ T Clk
BR_Range0
BR_Range1
BR_Range2
BR_Range3
after POR
t1
3367
2277
1735
1464
16.43
11650
11650
11650
11650
3311
2243
1709
1442
16.18
11470
11470
11470
11470
1624 ´ TClk
1100´ TClk
838 ´ TClk
707 ´ TClk
7936 ´ TClk
(see Figure 19 and
Figure 33)
t2
795
798
783
786
384.5 ´ TClk
385.5 ´
TClk
µs
Synchronization pulse
t3
265
265
261
261
128 ´ TClk
128 ´ TClk
µs
Delay until of
the program
window starts
t4
131
131
129
129
63.5 ´ TClk
63.5 ´ TClk
µs
Programming
window
t5
530
530
522
522
256 ´ TClk
256 ´ TClk
µs
Time frame
of a bit
(see Figure 33)
t6
1060
1060
1044
1044
512 ´ TClk
512 ´ TClk
µs
Programming
pulse (see
Figure 19 and
Figure 33)
t7
132
529
130
521
64 ´ TClk
256 ´ TClk
µs
Pulse on Pin
DATA at the end
of a data
stream (see
Figure 30)
9.5 ´ TClk
10.5 ´ TClk
8 ´ TClk
16.4
µs
µs
BR_Range =
BR_Range0
BR_Range1
BR_Range2
BR_Range3
TPulse
Configuration of the Receiver
Frequency of
the reset
marker
(see Figure 31)
Programming
start pulse (see
Figure 19 and
Figure 33)
BR_Range =
Programming
delay period
1
------------------------------4096 ´ T Clk
5632 ´ TClk
5632 ´ TClk
5632 ´ TClk
5632 ´ TClk
Hz
µs
µs
µs
µs
µs
33
4569A–RKE–12/02
Electrical Characteristics (Continued)
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
6.76438 MHz Osc.
(MODE: 1)
Parameter
Test Conditions
Symbol
Min.
Equivalent
acknowledge
pulse: E_Ack
(see Figure 33)
t8
Equivalent time
window (see
Figure 33)
OFF-bit
programming
window (see
Figure 19)
Typ.
4.90625 MHz Osc.
(MODE: 0)
Max.
Min.
265
265
t9
534
t10
tDelay2
Typ.
Variable Oscillator
Max.
Min.
261
261
534
526
930
930
0
0
0
0
66.2
33.1
16.56
8.3
Typ.
Max.
Unit
128 ´ TClk
128 ´ TClk
µs
526
258 ´ TClk
258 ´ TClk
µs
916
916
449.5 ´ TClk
449.5 ´ TClk
µs
16.6
8.3
4.15
2.07
0
0
0
0
16.3
8.2
4.08
2.04
0
0
0
0
1 ´ TXClk
1 ´ TXClk
1 ´ TXClk
1 ´ TXClk
µs
µs
µs
µs
66.2
33.1
16.56
8.3
65.2
32.6
16.3
8.2
65.2
32.6
16.3
8.2
4 ´ TXClk
4 ´ TXClk
4 ´ TXClk
4 ´ TXClk
4 ´ TXClk
4 ´ TXClk
4 ´ TXClk
4 ´ TXClk
µs
µs
µs
µs
Data Clock
Minimum delay
time between
edge at DATA
and DATA_CLK
(see Figure 26
and Figure 27)
BR_Range =
Pulswidth of
negative pulse
at Pin
DATA_CLK
(see Figure 26
and Figure 27)
BR_Range =
BR_Range0
BR_Range1
BR_Range2
BR_Range3
BR_Range0
BR_Range1
BR_Range2
BR_Range3
tP_DATA_CLK
Electrical Characteristics (Continued)
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
Parameters
Test Conditions
Current consumption
Sleep mode
(XTO and polling logic active)
IC active (start-up-, bit check-,
receiving mode) Pin DATA = H
FSK
ASK
Symbol
Min.
Typ.
Max.
Unit
ISoff
170
276
µA
ISon
7.5
7.1
9.1
8.7
mA
mA
IIP3
-28
ISLORF
-73
LNA Mixer (Input Matched According to Figure 6)
Third-order intercept point
LNA/mixer/IF amplifier
LO spurious emission at RFIn
Required according to I-ETS 300220
Noise figure LNA and mixer (DSB)
LNA_IN input impedance
at 433.92 MHz
at 315 MHz
1 dB compression point (LNA, mixer, Referred to RFin
IF amplifier)
34
NF
7
ZiLNA_IN
1.0 || 1.56
1.3 || 1.0
IP1db
-40
dBm
-57
dBm
dB
kW || pF
kW || pF
dBm
T5743
4569A–RKE–12/02
T5743
Electrical Characteristics (Continued)
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
Parameters
Test Conditions
Maximum input level
BER £ 10 ,
FSK mode
ASK mode
Symbol
Min.
Typ.
Max.
Unit
-22
-20
dBm
dBm
449
MHz
-93
-113
-90
-110
dBC/Hz
dBC/Hz
-55
-47
dBC
-3
Pin_max
Local Oscillator
Operating frequency range VCO
Phase noise VCO/LO
Spurious of the VCO
fVCO
fosc = 432.92 MHz
at 1 MHz
at 10 MHz
Capacitive load at Pin LF
XTO operating frequency
Series resonance resistor of the
crystal
L (fm)
at ± fXTO
KVCO
190
MHz/V
For best LO noise (design
parameter)
R1 = 820 W
C9 = 4.7 nF
C10 = 1 nF
BLoop
100
kHz
The capacitive load at Pin LF is
limited if bit check is used. The
limitation therefore also applies to
self polling.
CLF_tot
VCO gain
Loop bandwidth of the PLL
299
XTO crystal frequency, appropriate
load capacitance must be connected
to XTAL
fXTAL = 6.764375 MHz (EU)
fXTAL = 4.90625 MHz (US)
fXTO = 6.764 MHz,
fXTO = 4.906 MHz
Static capacitance at Pin XTO to
GND
10
nF
+30 ppm
MHz
RS
150
220
W
W
C0
6.5
pF
-113
-111
-110
-108
dBm
dBm
dBm
dBm
fXTO
-30 ppm
fXTAL
Analog Signal Processing
Input sensitivity ASK
300 kHz IF-filter
Input matched according to
Figure 6
ASK (level of carrier)
BER £ 10-3, BW = 300 kHz
fin = 433.92 MHz/315 MHz
VS = 5 V, Tamb = 25°C, fIF = 1 MHz
BR_Range0
BR_Range1
BR_Range2
BR_Range3
PRef_ASK
-109
-107
-106
-104
-111
-109
-108
-106
35
4569A–RKE–12/02
Electrical Characteristics (Continued)
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
Parameters
Test Conditions
Symbol
Input sensitivity ASK
600 kHz IF-filter
Input matched according to
Figure 6
ASK (level of carrier)
BER £ 10-3, BW = 600kHz
fin = 433.92 MHz/315 MHz
VS = 5 V, Tamb = 25°C, fIF = 1 MHz
BR_Range0
BR_Range1
BR_Range2
BR_Range3
PRef_ASK
Min.
Typ.
Max.
Unit
-108
-106.5
-106
-104
-110
-108.5
-108
-106
-112
-110.5
-110
-108
dBm
dBm
dBm
dBm
Sensitivity variation ASK for the full
operating range compared to
Tamb = 25°C, VS = 5 V
300 kHz and 600 kHz version
fin = 433.92 MHz/315 MHz
fIF = 1 MHz, PASK = PRef_ASK + DPRef
DPRef
+2.5
-1.5
dB
Sensitivity variation ASK for full
operating range including IF-filter
compared to Tamb = 25°C, VS = 5 V,
300 kHz version
fin = 433.92 MHz/315 MHz
fIF = 0.89 MHz to 1.11 MHz
fIF = 0.86 MHz to 1.14 MHz
PASK = PRef_ASK + DPRef
DPRef
+5.5
+7.5
-1.5
-1.5
dB
dB
600 kHz version
fin = 433.92 MHz/315 MHz
fIF = 0.79 MHz to 1.21 MHz
fIF = 0.73 MHz to 1.27 MHz
PASK = PRef_ASK + DPRef
DPRef
+5.5
+7.5
-1.5
-1.5
dB
dB
BR_Range0
df = ±16 kHz
df = ±10 kHz to ±30 kHz
PRef_FSK
-101
-99
-104
-105.5
-105.5
dBm
dBm
BR_Range1
df = ±16 kHz
df = ±10 kHz to ±30 kHz
PRef_FSK
-99
-97
-102
-103.5
-103.5
dBm
dBm
BR_Range2
df = ± 16 kHz
df = ±10 kHz to ±30 kHz
PRef_FSK
-97.5
-95.5
-100.5
-102
-102
dBm
dBm
BR_Range3
df = ±16 kHz
df = ±10 kHz to ±30 kHz
PRef_FSK
-95.5
-93.5
-98.5
-100
-100
dBm
dBm
Input sensitivity FSK
300 kHz IF-filter
36
Input matched according to
Figure 6
BER £ 10-3, BW = 300 kHz
fin = 433.92 MHz/315 MHz
VS = 5 V, Tamb = 25°C
fIF = 1 MHz
T5743
4569A–RKE–12/02
T5743
Electrical Characteristics (Continued)
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
Parameters
Test Conditions
Symbol
Min.
Typ.
Max.
Unit
Input sensitivity FSK
600 kHz IF-filter
Input matched according to
Figure 6
BER £ 10-3, BW = 600 kHz
fin = 433.92 MHz/315 MHz
VS = 5 V, Tamb = 25°C
fIF = 1 MHz
BR_Range0
df = ±16 kHz
df = ±10 kHz to ±100 kHz
PRef_FSK
-101
-99
-104
-105.5
-105.5
dBm
dBm
BR_Range1
df = ±16 kHz
df = ±10 kHz to ±100 kHz
PRef_FSK
-99
-97
-102
-103.5
-103.5
dBm
dBm
BR_Range2
df = ±16 kHz
df = ±10 kHz to ±100 kHz
PRef_FSK
-97.5
-95.5
-100.5
-102
-102
dBm
dBm
BR_Range3
df = ±16 kHz
df = ±10 kHz to ±100 kHz
PRef_FSK
-95.5
-93.5
-98.5
-100
-100
dBm
dBm
Sensitivity variation FSK for the full
operating range compared to
Tamb = 25°C, VS = 5 V
300 kHz and 600 kHz version
fin = 433.92 MHz/315 MHz
fIF = 1 MHz
PFSK = PRef_FSK + DPRef
DPRef
+3
-1.5
dB
Sensitivity variation FSK for the full
operating range including IF-filter
compared to Tamb = 25°C, VS = 5 V
300 kHz version
fin = 433.92 MHz/ 315 MHz
fIF = 0.89 MHz to 1.11 MHz
fIF = 0.86 MHz to 1.14 MHz
fIF = 0.82 MHz to 1.18 MHz
PFSK = PRef_FSK + DPRef
DPRef
+6
+8
+11
-2
-2
-2
dB
dB
dB
600 kHz version
fin = 433.92 MHz/ 315 MHz
fIF = 0.85 MHz to 1.15 MHz
fIF = 0.80 MHz to 1.20 MHz
fIF = 0.74 MHz to 1.26 MHz
PFSK = PRef_FSK + DPRef
DPRef
+6
+8
+11
-2
-2
-2
dB
dB
dB
12
3
dB
dB
S/N ratio to suppress inband noise
ASK mode
signals. Noise signals may have any FSK mode
modulation scheme
SNRASK
SNRFSK
Dynamic range RSSI ampl.
DRRSSI
Lower cut-off frequency of the data
filter
CDEM = 33 nF
Recommended CDEM for best
performance
BR_Range0 (default)
BR_Range1
BR_Range2
BR_Range3
1
f cu_DF = ----------------------------------------------------------2 ´ p ´ 30 kW ´ CDEM
fcu_DF
CDEM
60
0.11
0.16
39
22
12
8.2
dB
0.20
kHz
nF
nF
nF
nF
37
4569A–RKE–12/02
Electrical Characteristics (Continued)
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
Parameters
Test Conditions
Edge-to-edge time period of the
input data signal for full sensitivity
BR_Range0 (default)
BR_Range1
BR_Range2
BR_Range3
Upper cut-off frequency data filter
Upper cut-off frequency
programmable in 4 ranges
via a serial mode word
BR_Range0 (default)
BR_Range1
BR_Range2
BR_Range3
Reduced sensitivity
tee_sig
270
156
89
50
fu
2.8
4.8
8.0
15.0
Typ.
3.4
6.0
10.0
19.0
Max.
Unit
1000
560
320
180
µs
µs
µs
µs
4.0
7.2
12.0
23.0
kHz
kHz
kHz
kHz
dBm
(peak
level)
-71
-67
-76
-72
-81
-77
dBm
dBm
RSense = 100 kW, fin = 433.92 MHz,
at BW = 300 kHz
at BW = 600 kHz
-80
-76
-85
-81
-90
-86
dBm
dBm
RSense = 56 kW, fin = 315 MHz,
at BW = 300 kHz
at BW = 600 kHz
-72
-68
-77
-73
-82
-78
dBm
dBm
RSense = 100 kW, fin = 315 MHz,
at BW = 300 kHz
at BW = 600 kHz
-81
-77
-86
-82
-91
-87
dBm
dBm
DPRed
5
6
0
0
0
0
dB
dB
DPRed
DPRed
DPRed
DPRed
DPRed
DPRed
0
-3.5
-6.0
-9.0
-11.0
-13.5
VThRESET
1.95
Reduced sensitivity variation over
full operating range
RSense = 56 kW
RSense = 100 kW
PRed = PRef_Red + DPRed
Reduced sensitivity variation for
different values of RSense
Values relative to RSense = 56 kW
38
Min.
RSense connected from Pin Sens
to VS, input matched according to
Figure 6
RSense = 56 kW, fin = 433.92 MHz,
at BW = 300 kHz
at BW = 600 kHz
Threshold voltage for reset
Symbol
RSense = 56 kW
RSense = 68 kW
RSense = 82 kW
RSense = 100 kW
RSense = 120 kW
RSense = 150 kW
PRed = PRef_Red + DPRed
PRef_Red
dB
dB
dB
dB
dB
dB
2.8
3.75
V
T5743
4569A–RKE–12/02
T5743
Electrical Characteristics (Continued)
All parameters refer to GND, Tamb = -40°C to +105°C, VS = 4.5 V to 5.5 V, f0 = 433.92 MHz and f0 = 315 MHz, unless otherwise specified.
(For typical values: VS = 5 V, Tamb = 25°C)
Parameters
Test Conditions
Symbol
Min.
Typ.
Max.
Unit
0.35
0.08
0.8
0.3
20
20
45
85
V
V
V
µA
mA
°C
0.35 ´ VS
V
V
Digital Ports
Data output
- Saturation voltage Low
- max voltage at Pin DATA
- quiescent current
- short-circuit current
- ambient temperature in case of
permanent short-circuit
Data input
- Input voltage Low
- Input voltage High
Iol £ 12 mA
Iol = 2 mA
Voh = 20 V
Vol = 0.8 V to 20 V
Voh = 0 V to 20 V
Vol
Vol
Voh
Iqu
Iol_lim
tamb_sc
VIl
Vich
13
30
0.65 ´ VS
DATA_CLK output
- Saturation voltage Low
- Saturation voltage High
IDATA_CLK = 1 mA
IDATA_CLK = -1 mA
Vol
Voh
VS-0.4 V
0.1
VS-0.15 V
0.4
V
V
IC_ACTIVE output
- Saturation voltage Low
- Saturation voltage High
IIC_ACTIVE = 1 mA
IIC_ACTIVE = -1 mA
Vol
Voh
VS-0.4 V
0.1
VS-0.15 V
0.4
V
V
POLLING/_ON input
- Low level input voltage
- High level input voltage
Receiving mode
Polling mode
VIl
VIh
0.8 ´ VS
0.2 ´ VS
V
V
MODE input
- Low level input voltage
- High level input voltage
Division factor = 10
Division factor = 14
VIl
VIh
0.8 ´ VS
0.2 ´ VS
V
V
0.2 ´ VS
V
TEST input
- Low level input voltage
Test input must always be set to Low
VIl
39
4569A–RKE–12/02
Ordering Information
Extended Type Number
Package
Remarks
T5743P3-TG
SO20
Tube, IF bandwidth of 300 kHz
T5743P3-TGQ
SO20
Taped and reeled, IF bandwidth of 300 kHz
T5743P6-TG
SO20
Tube, IF bandwidth of 600 kHz
T5743P6-TGQ
SO20
Taped and reeled, IF bandwidth of 600 kHz
Package Information
9.15
8.65
Package SO20
Dimensions in mm
12.95
12.70
7.5
7.3
2.35
0.25
0.25
0.10
0.4
10.50
10.20
1.27
11.43
20
11
technical drawings
according to DIN
specifications
1
40
10
T5743
4569A–RKE–12/02
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Printed on recycled paper.
4569A–RKE–12/02
xM