ATMEL ATA5283P-6AQJ

Features
•
•
•
•
•
•
•
•
Wake-up Function for a Microcontroller with Preamble Detection
1 mVrms Sensitivity
1 µA Standby Current
Power Supply: 2V to 3.8V
Baud Rate: up to 4 kbps (ASK Modulation)
Operation Temperature: up to 125°C
Withstands +175°C
Few External Components
Interface IC for
125 kHz
Wake-up
Function
Application
• Tire Pressure Monitoring (TPM)
1. Description
The ATA5283 is a 125 kHz ultra-low power receiver used for the wake-up function of
Tire Pressure Monitoring (TPM) application. The sensitive input stage of the IC amplifies and demodulates the carrier signal from the antenna coil to a digital output signal
for a microcontroller. During the standby mode the preamble detection unit monitors
the incoming signal and activates the wake-up output and the data output, if the IC
receives a proper 125 kHz carrier signal.
ATA5283
By combining the IC with an antenna coil, a microcontroller, an RF transmitter/transceiver, a battery, temperature- and pressure sensor, it is possible to design a
complete Tire Pressure Monitoring system (TPM).
Figure 1-1.
Block Diagram
Battery
VDD
Lx
COIL
ATA5283
Amplifier
with AGC
RESET
Vref
Conditioner
Preamble
check
N_WAKEUP
N_DATA
TST1
TST2
GND
4598H–AUTO–03/07
2. Pin Configuration
Figure 2-1.
Pinning TSSOP8L
COIL
TST1
TST2
VSS
Figure 2-2.
2
1
2
3
4
8
7
6
5
VDD
N_WAKEUP
N_DATA
RESET
Pin Description
Pin
Symbol
Function
1
COIL
Antenna coil input
2
TST1
Test pin (reserved)
3
TST2
Test pin (reserved)
4
VSS
Signal ground
5
RESET
External reset input
6
N_DATA
Data signal
7
N_WAKEUP
8
VDD
Low active wake-up signal for microcontroller
Battery voltage
ATA5283
4598H–AUTO–03/07
ATA5283
3. Functional Description
The ATA5283 is an ultra-low power ASK receiver. Without a carrier signal it operates in the
standby listen mode. In this mode it monitors the coil input with a very low current consumption.
To activate the IC and the connected control unit, the transmitting stage must send the preamble
carrier burst. After a preamble is detected the IC is activated. It adapts the gain of the input stage
and enables the wake-up and the data output. The first gap at the end of the preamble generates a wake-up signal for the microcontroller. After that the receiver outputs the data signal at
N_DATA. To return the IC into the standby listen mode it must be reset via the RESET input.
3.1
AGC Amplifier
The input stage contains an Automatic Gain Control (AGC) amplifier to amplify the input signal
from the coil. The gain is adjusted by the automatic gain control circuit if a preamble signal is
detected. The high dynamic range of the AGC enables the IC to operate with input signals from
1 mVrms to 1.1Vrms. After the AGC settling time the amplifier output delivers a 125 kHz signal with
an amplitude adjusted for the following evaluation circuits’ preamble detection, signal conditioner, wake-up.
3.2
Preamble Detection
Before data transmission the IC stays in standby listen mode. To prevent the circuit from unintended operations in a noisy environment the preamble detection circuit checks the input signal.
A valid signal is detected by a counter after 192 carrier periods without interrupts. Short interrupts which are suppressed by the signal conditioner are tolerated. When a valid carrier
(preamble) is found the circuit starts the automatic gain control. It requires up to 512 carrier periods to settling. The complete preamble should have 704 carrier periods minimum. The preamble
is terminated and the data transfer is started with the first gap (Start Gap) in the carrier (see Figure 3-1).
Figure 3-1.
Communication Protocol
Preamble
> 5.64 ms
Procedure
192 Periods
of LF
Start
gap
Data
> 512 Periods
of LF
Signal
N_DATA
N_WAKEUP
RESET
Gain
control
Current
profile
No gain
control
1 µA
AGC
adjustment
Gain control
active
2 µA
No gain
control
0.5 µA
3
4598H–AUTO–03/07
3.3
Automatic Gain Control
For a correct demodulation the signal conditioner needs appropriate internal signal amplitude.
To control the input signal the ATA5283 has a build in digital AGC. The gain control circuit regulates the internal signal amplitude to the reference value (Ref2, Figure 3-2). It decreases the
gain by one step if the internal signal exceeds the reference level for two periods and it
increases the gain by one step if eight periods do not achieve the reference level. In the standby
listen mode the gain is reset to the maximum value. If a valid preamble signal (192 valid carrier
clocks) is detected the automatic gain control is activated.
Note:
With the variation of the gain the coil input impedance changes from high impedance to minimal
143 kΩ because of the internal regulator circuit (see Figure 3-8 on page 8).
Figure 3-2.
Automatic Gain Control
Transmitted
signal
Coil
input
Gain control
reference
Ref. 2
Gap detection Ref. 1
reference
Gain controlled
signal
100%
50%
Internal comparator
signal
N_DATA
4
ATA5283
4598H–AUTO–03/07
ATA5283
3.4
Signal Conditioner
The signal conditioner demodulates the amplifier output signal and converts it to a binary signal.
It compares the carrier signal with the 50% reference level (see Ref1 in Figure 3-3) and delivers
a logical 1, if the carrier signal stays below the reference and a logical 0, if it exceeds the reference level. A smoothing filter suppress the space between the half-waves as well as a few
missing periods in the carrier and glitches during the gaps.
The output signal of the signal conditioner is used as the internal data signal for the data output,
the wake-up logic and the preamble detection.
The timing of the demodulated data signal is delayed related to the signal at the transmitting
end. This delay is a function of the carrier frequency, the behavior of the smoothing filter and the
antenna Q-factor. The smoothing filter causes a delay of 3 to 6 periods (see tb and td in Figure
3-3). The rest of the delay is caused by the build-up time of the antenna signal and is conditioned on the Q-factor (see ta and tc in Figure 3-3).
Figure 3-3.
Output Timing
Ref.2
100%
Ref.1
50%
Coil
input
Comparator
output
N_DATA
tb
tc
ta
td
tON
tOFF
The following diagrams show the delay of the data signal as a function of the antenna Q-factor.
Figure 3-4.
Turn On Delay Time (tON) versus Antenna Q-Factor
250
ffield = 125 kHz
200
typ.
ton (µs)
max.
150
100
min.
50
0
0
10
20
30
40
50
Q-factor
5
4598H–AUTO–03/07
Figure 3-5.
Turn Off Delay Time (toff) versus Antenna Q-Factor
200
180
ffield = 125 kHz
160
toff (µs)
140
typ.
max.
120
100
80
60
min.
40
20
0
0
10
20
30
40
50
Q-factor
3.5
Data Output
The data output N_DATA outputs the demodulated and digitized LF signal according to the
envelope of the antenna input signal. In the standby mode the N_DATA output is disabled and
set to level 1. It is enabled by the wake-up signal and it outputs 1 level if the IC detects the carrier signal and a 0 level during the gaps (see Figure 3-1 on page 3).
As the circuit does not check the received data (except the preamble), it is up to the user to
choose the kind of encoding (pulse distance, Manchester, bi-phase...) wanted.
3.6
Wake-up Signal
The wake-up signal (N_WAKEUP) indicates that the ATA5283 has detected the end of a preamble signal and has left the standby mode. It can be used as a wake-up or a chip select signal for
an external device (see Figure 3-1 on page 3).
After a preamble is detected the first valid gap (Start Gap) sets the N_WAKEUP output to low
and enables the data output N_DATA. The N_WAKEUP holds the low level until the IC is reset
to the standby mode by a reset signal.
3.7
Reset
The IC is reset either by the internal POR circuit during a power on sequence or by a high pulse
at the RESET pin. After the reset all internal counters are in the initial state and the IC is in the
standby listen mode.
The POR circuit generates a reset while the supply voltage VDD is below the power on reset
threshold VPOR and release the function of the IC if VDD exceeds this threshold.
A high signal at the RESET pin resets the complete circuit. If the IC is activated a reset signal is
necessary to activate the standby listen mode.
The RESET pin can also be used to hold the IC in a power down state. In this state the IC is out
of operation and the current consumption is below the standby current.
Note:
6
The RESET pin is high impedance CMOS input. To avoid floating effects like undefined input
states and malfunctions it should not be open.
ATA5283
4598H–AUTO–03/07
ATA5283
3.8
Standby Listen Mode
In the standby listen mode the IC monitors the coil input with a very low current consumption.
The automatic gain control is switched off and the gain is set to the maximum value. The
N_DATA and the N_WAKEUP output are set to a high level.
Before the controller enters its standby mode after the communication, it should activate the
standby listen mode of the ATA5283 with a reset signal. This measure ensures that the IC
enters the power saving standby mode and that the IC wakes the controller correctly with the
next preamble signal.
3.9
Applications
Figure 3-6 shows a typical TPM application of the ATA5283. Combined with the antenna resonant circuit the ATA5283 is used as wake-up receiver for the microcontroller and the connected
temperature- and pressure-sensor.
Note:
Figure 3-6.
To avoid supply voltage ripples to affect the microcontroller, an RC filter (R1 = 100Ω, C1 = 10 nF)
is recommended.
Application
R1
125 kHz
Central
board
controller
8
LA
Antenna
driver
ATA5275
CA
1
Amplifier
with
AGC
C1
ATA5283
5
RESET
7
N_WAKEUP
6
N_DATA
Temp.
sensor
Micro
controller
Pressure
sensor
Vref
2
3
4
UHF Rx
UHF Tx
T5743
433 kHz
ATAR862
7
4598H–AUTO–03/07
Figure 3-7.
Pin Connection and Pin Protection
ATA5283
COIL_X
1
8
VDD
7
N_WAKEUP
6
N_DATA
5
RESET
Divider impedance
143 kΩ to 5 MΩ
VDD
TST1
VDD
2
2 kΩ
VDD
TST2
VDD
VDD
3
2 kΩ
VDD
VSS
4
1 kΩ
Figure 3-8.
Coil Input Impedance
10000
max.
typ.
Z (kΩ)
min.
1000
100
1
10
100
1000
10000
Coil Input Signal (mVpp)
8
ATA5283
4598H–AUTO–03/07
ATA5283
4. Absolute Maximum Ratings
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating
only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this
specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Parameters
Symbol
Value
Unit
Power supply
VDD
–0.3 to +6.5
V
Input voltage (except coil inputs)
VIN
VSS – 0.3 < VIN < VDD + 0.3
V
Input current coil
ICI
±10
mA
VCI
VDD – 3.5 < VCI < VDD + 3.5
V
ESD protection (human body)
VESD
4
kV
Operating temperature range
Tamb
–40 to +125
°C
Withstanding 175°C
tTEMP
30
min.
Storage temperature range
Tstg
–40 to +150
°C
Soldering temperature
Tsld
260
°C
Symbol
Value
Unit
RthJA
210
K/W
Symbol
Value
Unit
Input voltage coil
5. Thermal Resistance
Parameters
Thermal resistance junction ambient
6. Operating Range
Parameters
Power supply range
VDD
2 to 3.8
V
Operating temperature range
TOP
–40 to +125
°C
9
4598H–AUTO–03/07
7. Electrical Characteristics
VSS = 0V, VDD = 2V to 3.8V, Tamb = –40° C to +105°C, characterized up to 125°C, unless other specified
No.
1
1.1
Parameters
Test Conditions
Pin
Symbol
Min.
Typ.
Max.
Unit
Type*
8
VDD
2
3.2
3.8
V
A
0.8
µA
A
0.8
µA
A
0.8
µA
C
Reset supply current +105
1.0
µA
A
Reset supply current +125
1.5
µA
C
Supply current
(standby listen mode) –40
1.4
µA
A
Supply current
(standby listen mode) +25
1.5
µA
A
1.6
µA
C
Supply current
(standby listen mode) +105
1.6
µA
A
Supply current
(standby listen mode) +125
1.7
µA
C
Supply current with carrier
(AGC active) –40
4.0
µA
A
Supply current with carrier
(AGC active) +25
4.1
µA
A
4.2
µA
C
Supply current with carrier
(AGC active) +105
4.2
µA
A
Supply current with carrier
(AGC active) +125
4.2
µA
C
±1.4
Vp
A
±1.6
Vp
A
±1.8
Vp
A
Power Supply and Coil Limiter
Power supply
Reset supply current –40
Reset supply current +25
1.2
1.3
1.4
1.5
1, 2, 3,
8
Reset supply current +85
1, 2, 3,
8
Supply current
(standby listen mode) +85
1,2, 3,
8
Supply current with carrier
(AGC active) +85
Coil input voltage referred to
VDD (Input coil limiter for
channels X, Y, Z)
0.4
IDDR
IDDL
1.1
2
IDD
ICI = ± 1 mA
VDD = 2V
ICI = ± 1 mA
VDD = 3.2V
1-3
VC
ICI = ± 1 mA
VDD = 3.8V
2
Amplifiers
2.1
Wake-up sensitivity
125 kHz input signal
7
VSENS
1
mVrms
A
2.2
Bandwidth
Without coil
6
BW
150
2.2
kHz
C
2.3
Upper corner frequency
Without coil
6
fu
180
kHz
C
2.4
Lower corner frequency
Without coil
6
fo
30
kHz
C
2.5
Input impedance
f = 125 kHz
1
RIN
kΩ
A
Input capacitance
VIN ≥ 1 mVrms at
125 kHz
1
CIN
pF
C
2.6
143
10
*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter
10
ATA5283
4598H–AUTO–03/07
ATA5283
7. Electrical Characteristics (Continued)
VSS = 0V, VDD = 2V to 3.8V, Tamb = –40° C to +105°C, characterized up to 125°C, unless other specified
No.
Parameters
3
Automatic Gain Control
3.1
Preamble detection time
Test Conditions
Pin
VIN ≥ 3 mVrms at
125 kHz
Symbol
Min.
Typ.
tDAGC
192
tAGC
tAGC
tAGC
tAGC
tAGC
0
48
220
292
450
Max.
Unit
Type*
Periods
B
Periods
C
f = 125 kHz
3.2
AGC adjustment time
3.3
Signal change rate
(gap detection)
3.4
AGC correction time
(no gap detection)
VIN = 1 mVrms
VIN = 3 mVrms
VIN = 30 mVrms
VIN = 100 mVrms
VIN = 1Vrms
512
Coil input signal 100%
to 37% (τ )
1
tEOS
20
Periods
C
Coil input signal:
50 to 100% changing
1
tCORR
52
Periods
C
Coil input signal:
100 to 50% changing
1
tCORR
208
Periods
C
3.5
Data rate (Q < 20)
125 kHz ASK
DR
4
Kb/s
A
3.6
Delay time RF signal to data
125 kHz ASK
tON
40
µs
A
3.7
Delay time RF signal to data
125 kHz ASK
tOFF
40
µs
A
V
A
µs
A
4
4.1
4.1.1
Interface
Reset input level high
Reset pulse width
VRESET = VDD
5
VHRESET
0.8 ×
VDD
5
tRESET
20
5
VLRESET
0
0.2 ×
VDD
V
C
VDD
4.2
Reset input level low
4.3
Reset input leakage current
low
VRESET = VSS
5
IIL
-0.2
0
µA
A
4.4
Reset input leakage current
high
VRESET = VDD
5
IIH
0
0.2
µA
A
4.5
N_WAKEUP output level high INWAKEUP = –100 µA
7
VHNWAKE
0.8 ×
VDD
VDD
V
A
4.6
N_WAKEUP output level low
7
VLNWAKE
0
0.2 × VDD
V
A
VDD
V
A
0.2 × VDD
V
A
1.9
V
A
tPON
100
ms
C
TSbydel
800
µs
C
200
µs
C
INWAKEUP = 100 µA
4.7
N_DATA output level high
IN_DATA = –100 µA
6
VHNDATA
0.8 ×
VDD
4.8
N_DATA output level low
IN_DATA = 100 µA
6
VLNDATA
0
VPOR
1
5
5.1
5.2
5.2.1
5.3
Power Supply and Reset
VDD power on reset threshold
Power-up time
Switch on VDD to circuit
active
Standby reactivation delay
after pulse reset
f = 125 kHz
RESET reactivation caused by
tBDN = 500 ns
negative spikes on VDD
7
tRST
10
1.5
*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter
11
4598H–AUTO–03/07
8. Ordering Information
Extended Type Number
Package
Remarks
ATA5283P-6AQJ
TSSOP8L
5000 pieces, taped and reeled, Pb-free
ATA5283P-6APJ
TSSOP8L
500 pieces, taped and reeled, Pb-free
9. Package Information
3±0.1
+0.06
0.31-0.07
0.65 nom.
3.8±0.3
4.9±0.1
+0.0
0.1±0.05
3±0.1
0.15-0.025
0.85±0.05
+0.05
1-0.15
Package: TSSOP 8L
Dimensions in mm
3 x 0.65 = 1.95 nom.
8
5
technical drawings
according to DIN
specifications
Drawing-No.: 6.543-5083.01-4
1
4
Issue: 2; 15.03.04
12
ATA5283
4598H–AUTO–03/07
ATA5283
10. Revision History
Please note that the following page numbers referred to in this section refer to the specific revision
mentioned, not to this document.
Revision No.
History
4598H-AUTO-03/07
• Number 5.2.1 in section 7 “Electrical Characteristics” on page 11 added
4598G-AUTO-01/07
• Put datasheet in a new template
• Pb-free logo on page 1 deleted
4598F-AUTO-09/05
•
•
•
•
Put datasheet in a new template
Pb-free logo on page 1 added
Heading Rows on Table “Absolute Maximum Ratings” on page 9 added
Ordering Information on page 12 changed
13
4598H–AUTO–03/07
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4598H–AUTO–03/07