PTC PT4317

Preliminary
PT4317
Low Power 315/433MHz OOK/ASK
Superheterodyne Receiver with
SAW-Based Oscillator
DESCRIPTION
The PT4317 is a low power single chip OOK/ASK
superheterodyne receiver for the 315MHz and
434MHz frequency bands that offers a high level of
integration and requires few external components.
The PT4317 consists of a low-noise amplifier (LNA),
down-conversion mixer, SAW-based local oscillator,
on-chip gm-C band-pass filter, intermediate frequency
(IF) limiting amplifier stage with received-signalstrength indicator (RSSI), and analog baseband data
recovery circuitry (data filter, peak detector, and data
slicer). The PT4317 is available in a 16-pin SSOP
package.
FEATURES
•
•
•
•
•
Low current consumption (4.7mA at VDD=5.0V)
2.4V to 5.5V supply voltage operation range
Optimized for 315MHz or 434MHz ISM Band
Saw-based oscillator with low frequency drift
On-chip IF filter with better adjacent channel
rejection capability
• Power down mode with very low supply current
(<1μA)
• Low external parts count
• 16-pin SSOP package
APPLICATIONS
•
•
•
•
•
•
Remote Keyless Entry (RKE) systems
Remote control systems
Garage door openers
Alarm systems
Security systems
Wireless sensors
BLOCK DIAGRAM
Tel: 886-66296288‧Fax: 886-29174598‧ http://www.princeton.com.tw‧2F, 233-1, Baociao Road, Sindian, Taipei 23145, Taiwan
PT4317
APPLICATION CIRCUIT
BILL OF MATERIALS
Part
Value
Unit
Description
315MHz
433.92MHz
L1
47n
27n
H
Antenna input matching, coil inductor.
C1
1.8p
1.8p
F
Antenna input matching.
C2/C4
100n
100n
F
Power supply de-coupling capacitor.
C3
Note1
470p
470p
F
Data filter capacitor.
C5
Note1
150p
150p
F
C6
100n
100n
F
C7Note1
22n
22n
F
Data filter capacitor.
Peak detector bypass capacitor(average
mode)
Data slicer threshold charge capacitor.
—
—
F
SAW oscillator frequency trimming capacitors.
R1/R4
10K
10K
Ω
MCU interface resistor (option).
R2
270K
270K
Ω
IF filter tuning resistor
R3
10
10
Ω
Power supply de-coupling resistor (option).
316.8
435.72
MHz
SAW oscillator.
PT4317 IC
PT4317 IC
U1
Receiver chip.
C8/C9
S1
Note2
Note3
U1
Notes:
1. The data filter and slicer are optimized for 2Kb/s data rate in this application circuit.
2. The C8 and C9 are trimming capacitors for fine tuning the oscillation frequency of SAW oscillator.
3. S1 is the SAW resonator, and the frequency drift tolerance of ±75KHz is acceptable.
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PT4317
ORDER INFORMATION
Valid Part Number
PT4317-X
Package Type
16 Pins, SSOP, 150mil
Top Code
PT4317-X
PIN CONFIGURATION
PIN DESCRIPTION
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Pin Name
CE
REXT
RFIN
VSSLNA
I/O
I
O
I
G
Description
Chip enable
IF filter tuning resistor
RF input
Ground for LNA
NC
—
No connection
5
VREG
DFFB
DSP
VDD5
OPP
PDOUT
DSN
DATA
VSS
OSCIN
OSCOUT
I/O
I
I
P
I
O
I
O
G
I
O
Voltage regulator output
Data filter feedback point
Positive input of data slicer (data filter output)
5V power supply voltage
Non-inverting op-amp input
Peak detector output
Negative input of data slicer
Data output
Ground
SAW oscillator input
SAW oscillator output
6
7
8
9
10
11
12
13
14
15
16
3
Pin No.
1
2
3
4
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PT4317
FUNCTION DESCRIPTION
POWER SUPPLY
PT4317 includes an internal voltage regulator to supply power to all receiver blocks. Only the VDD5 pin (pin 9) must be
connected to the external supply voltage, along with series-R, shunt-C filtering. Bypass capacitors should be placed as
close as possible to the voltage regulator output pin (pin 6). The PT4317 chip supports operation over the supply voltage
range from 2.4V to 5.5V.
RF FRONT-END
The RF front-end of the receiver part employs a superheterodyne architecture that achieves good performance
characteristics, including low noise figure, high voltage conversion gain, and excellent reverse isolation. The RF
front-end down-converts the input radio frequency (RF) signal into an intermediate frequency (IF) signal at 1.8MHz.
According to the block diagram, the RF front-end consists of an LNA, down-conversion mixer, and a surface acoustic
wave (SAW) oscillator signal with buffer amplifier to drive the mixer’s LO input. The output of the RF front-end is fed into
the IF chain for channel-select filtering and demodulation.
The RF downconverter does not include inherent suppression of the image frequency. Depending upon the particular
application and the system's environmental conditions, a RF front-end filter may be added. If image rejection or good
blocking immunity is a relevant system parameter, a band-pass filter must be placed in front of the LNA. This filter may
be a SAW or LC-based filter (e.g. helix type).
The RF input pin (pin 3) may be matched to 50Ω with a shunt inductor from the RF input pin to ground and a series
capacitor from the RF input to the antenna. An example of the input matching network is shown in the figure below and
the input impedance of the PT4317 for 315 and 434MHz frequency bands is listed in the right-hand side table. The
component values given in the BOM for the application circuit shown on page 2 are nominal values only. Actual inductor
and capacitor values may be different, depending upon the PCB material, PCB thickness, ground configuration, and
length of PCB traces.
RF Frequency fRF
315MHz
433.92MHz
RFIN Input Impedance (Pin 3)
10.49-j231.27
6.5921-j160.35
IF CHANNEL SELECT FILTER (CSF)
Out-of-band interference is rejected by means of a 6th-order Chebyshev gm-C filter centered at a frequency of 1.8MHz.
To compensate for manufacturing tolerances, the IF CSF is auto-tuned after power-up. The IF filter auto-tuning
mechanism requires an external resistor (R2) of 270K. By the way, the variation of the value of R2 within 1% is better.
SAW OSCILLATOR
The SAW oscillator is configured as a Pierce oscillator, but consists of a cascade of three amplifiers instead of a single
amplifier. Although the circuit configuration is quite similar to the conventional Pierce oscillator, this configuration is
capable of generating a much higher value of negative resistance. The SAW resonator is connected between pin 15
(OSCIN) and pin 16 (OSCOUT).
The capacitors (C8 and C9) connected from pin 15 (OSCIN) and pin 16 (OSCOUT) to ground is used for adjusting the
oscillation frequency. In general, those capacitors are unnecessary if the frequency drift can be ignored. The SAW
oscillator circuit is shown in the left-hand side figure below, and an equivalent circuit of a SAW resonator is shown on the
right-hand side. The component values of the equivalent circuit are also listed below for reference.
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PT4317
SAW Resonator Equivalent Circuit
Part Number
SRA316D800A01-SD11
MFSRA435.72A01-SD11
Center Frequency (MHz)
316.8
435.72
RS (Ω)
19
18
LS (μH)
119.06
85.38
CS (pF)
0.00213
0.00156
CL (pF)
2.4
1.7
For down-converting the RF signal to the IF frequency, a suitable SAW oscillation frequency must be chosen. In the
PT4317 chip, since the center frequency of the IF CSF is located at 1.8MHz, the following equation may be used to
calculate an appropriate SAW oscillator frequency:
SAW Oscillator Freq. = TX Freq. ± 1.8 MHz
In addition to a SAW resonator, the resonant circuit may also be achieved by an L-C tank circuit. A recommended circuit
for an L-C tank is shown in the following figure.
RF Frequency
(MHz)
315
433.92
C9 (pF)
C10 (pF)
Trimmer L2 (H)
100
100
10
5.6
2.5T
1.5T
LIMITER/RSSI
The limiter is an AC coupled, multi-stage amplifier with a cumulative gain of approximately 70dB that has a band-pass
characteristic centered near 1.8MHz. The –3dB bandwidth of the limiter is around 2MHz. The limiter circuit also
produces an RSSI voltage that is directly proportional to the input signal level with a slope of approximately 10mV/dB.
This signal is used by the succeeding baseband circuitry to demodulate ASK-modulated receive signals.
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PT4317
DATA FILTER
The data filter is also implemented as a 2nd-order low-pass Sallen-Key filter. The pole locations are set by the
combination of two on-chip resistors and two external capacitors. Adjusting the value of the external capacitors changes
the corner frequency and allows for optimization with different data rates. The corner frequency should be set to
approximately 1.5 times the highest expected data rate from the transmitter. An ideal Sallen-Key filter is shown below.
Utilizing the on-board voltage follower and the two 100K on-chip resistors, a 2nd-order Sallen-Key low pass data filter may
be constructed by adding two external capacitors between pins 7 (DFFB) and 8 (DSP) and to pin 10 (OPP) as depicted
in the Application Circuit (see page 2). The following table shows the recommended values of the capacitors for different
data rates.
Data Rate
< 2Kb/s
2Kb/s ~ 10Kb/s
10Kb/s ~ 20Kb/s
20Kb/s ~ 40Kb/s
> 40Kb/s (see Note)
C3 (pF)
1000
470
150
56
15
C5 (pF)
270
150
56
15
4.7
Note: the maximum data rate supported by the PT4317 is 50Kb/s
PEAK DETECTOR
The peak detector generates a DC voltage which is proportional to the peak value of the received data signal. An
external R-C network is necessary. The peak detector input is connected to the data filter output, which is connected to
pin 8 (DSP), and its output signal can be used as a reference for the data slicer. The R-C time constant is calculated with
the driving current of the data filter, 250μA. The following table shows the recommended values of the resistor and
capacitors for different data rates.
Data Rate
R5 (Ω)
C7 & C12 (F)
2Kb/s
250k
15n
10Kb/s
250k
3n
20Kb/s
250k
1.5n
40Kb/s
250k
680p
Note: the maximum data rate supported by the PT4317 is 50Kb/s
The circuit which utilizes the peak detector for faster start-up is depicted in the following figure.
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PT4317
DATA SLICER
The data slicer consists chiefly of a fast comparator, which allows for a maximum received data rate up to 50Kb/s. The
maximum achievable data rate also depends upon the IF filter bandwidth. Both data slicer inputs are accessible off-chip
to allow for easy adjustment of the slicing threshold. The output delivers a digital data signal (CMOS level) for
subsequent circuits. The self-adjusting threshold on pin 12 (DSN) is generated by an R-C network or peak detector
depending upon the baseband coding scheme.
The suggested data slicer configuration uses an internal 25KΩ resistor connected between DSN and DSP with a
capacitor from DSN to ground as shown in the following figure. The cut-off frequency of the R-C integrator must be set
lower than the lowest frequency appearing in the data signal to minimize distortion in the output signal.
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PT4317
DEMODULATION
Using different circuit combinations, the PT4317 is capable of achieving three demodulation modes: “Peak Mode”,
“Squelch Mode” and “Average Mode.”
PEAK MODE
The peak detector circuit can contributes an instantaneous voltage jump on node “DSN” through capacitive voltage
divider formed by C7 and C12. After the jump, the voltage on node “DSN” will decay to a steady–state value determined
by the resistive divider formed by Rin and R5. By selecting the suitable value of R5, C7 and C12, the threshold voltage
for comparison can be rapidly set through the help of peak detector circuit (see the ”PEAK DETECTOR” section).
SQUELCH MODE
In the absence of a RF signal, the data filter outputs a DC voltage with a time-varying noise which the peak-to–peak
voltage value is around 20mV. The noise makes the non-inverting input voltage of the data slicer swing back and forth
across the DSN threshold voltage, causing the comparator’s output to switch back and forth between the supply voltage
and ground randomly. The squelch mode operation adds a threshold deviation (DC offset) on the DSN threshold that
stop the effect. However, the sensitivity will be sacrificed. The recommended value for the resistor R6 is 1.2MΩ (The
sensitivity loss is about 4dB). The DC offset can be adjusted by changing the resistance of R6 and VREG voltage. A
larger DC offset will introduce more sensitivity loss.
AVERAGE MODE
When the “Average Mode” has been set according to the figure shown in the DATA SLICER section above, the DATA
output will exhibit a toggling behavior similar to random noise. In this mode, better sensitivity may be achieved, but noise
immunity is worse than in “Peak Mode.”
SENSITIVITY AND SELECTIVITY
In digital radio systems, sensitivity is often defined as the lowest signal level at the receiver input that will achieve a
specified bit error rate (BER) at the output. The sensitivity of the PT4317 receiver is typically –106dBm (ASK modulated
with 2Kb/s, 50% duty cycle square wave) to achieve a 0.1% BER when its input is matched for a 50Ω signal source.
The selectivity is governed by the response of the receiver front-end circuitry, the IF channel select filter (CSF), and the
data filter. Note that the IF filter provides not only channel selectivity, but also the interference rejection. Within the pass
band of the receiver, no rejection for interfering signals is provided.
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PT4317
POWER-DOWN CONTROL
The chip enable (CE) pin controls the power on/off behavior of the PT4317. Connecting CE to “HIGH” sets the PT4317
to the normal operation mode; connecting CE to “LOW” sets the PT4317 to standby mode. The current consumption of
the PT4317 is lower than 1μA in standby mode. Once enabled, the PT4317 requires <5ms to recover received data. A
timing plot showing the response of the data output once the PT4317 is enabled is shown in the following figure.
ANTENNA DESIGN
For a λ/4 dipole antenna and operating frequency, f (in MHz), the required antenna length, L (in cm), may be calculated
by using the formula
7132
L=
f
For example, if the frequency is 315MHz, then the length of a λ/4 antenna is 22.6 cm. If the calculated antenna length
is too long for the application, then it may be reduced to λ/8, λ/16, etc. without degrading the input return loss.
However, the RF input matching circuit may need to be re-optimized. Note that in general, the shorter the antenna, the
worse the receiver sensitivity and the shorter the detection distance. Usually, when designing a λ/4 dipole antenna, it is
better to use a single conductive wire (diameter about 0.8mm to 1.6mm) rather than a multiple core wire.
If the antenna is printed on the PCB, ensure there is neither any component nor ground plane underneath the antenna on
the backside of PCB. For an FR4 PCB (εr=4.7) and a strip-width of 30mil, the length of the antenna, L (in cm), is
calculated by
c
L=
where “c” is the speed of light (3 x1010 cm/s)
4× f × εr
PCB LAYOUT CONSIDERATION
Proper PCB layout is extremely critical in achieving good RF performance. At the very least, using a two-layer PCB is
strongly recommended, so that one layer may incorporate a continuous ground plane. A large number of via holes
should connect the ground plane areas between the top and bottom layers. Note that if the PCB design incorporates a
printed loop antenna, there should be no ground plane beneath the antenna.
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PT4317
Careful consideration must also be paid to the supply power and ground at the board level. The larger ground area plane
should be placed as close as possible to the VSS and VSSLNA pins. To reduce supply bus noise coupling, the power
supply trace should be incorporate series-R, shunt-C filtering as shown below.
If the power source is capable of supplying a stable voltage, C’ may be ignored. In some applications, the DC source
may be supplied from a simple AC-DC transformer. In such cases, the DC voltage level could be unstable and may
adversely affect ASK/OOK receiver sensitivity. A solution may be to increase C to an appropriately large value while
continuing to make the power source as stable as possible.
Finally, in an RF system, it is extremely important to keep the LNA or RF signal traces away from large voltage swing
signals and digital data signal traces to avoid unnecessary interference. A representative layout of a PT4317
demo-board is shown on page 14.
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PT4317
ABSOLUTE MAXIMUM RATINGS
Parameter
Supply Voltage Range
Analog I/O Voltage
Digital I/O Voltage
Operating Temperature Range
Storage Temperature Range
Soldering Temperature
Soldering Time
Symbol
Min.
Max.
Unit
VDD5
–
–
Topr
Tstg
TSLD
tSTG
-0.3
-0.3
-0.3
-40
-55
6
3
6
+85
+125
V
V
V
°C
°C
°C
S
225
10
RECOMMENDED OPERATING CONDITIONS
(VSS=0V)
Parameter
Symbol
Supply Voltage Range
Operating Temperature
VDD5
TA
Min.
Value
Typ.
Max.
2.4
-40
5.0
27
5.5
85
V
°C
Unit
Unit
PACKAGE THERMAL CHARACTERISTIC
Parameter
From Chip Conjunction Dissipation to
External Environment
From Chip Conjunction Dissipation to
Package Surface
PRE1.0
Symbol
Condition
Rja
Rjc
TA=27°C
11
Min.
Typ.
Max.
–
37.15
–
–
1
1.8
°C/W
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PT4317
ELECTRICAL CHARACTERISTICS
Nominal conditions: VDD5=5.0V, VSS=0V, CE=“HIGH”, TA=+27°C, fRF=433.92MHz.
Parameter
Symbol
Conditions
Min.
General Characteristics
Operating Frequency Range
fRF
250
Connect the supply voltage to
2.4
Supply Voltage
VDD5
VDD5 pin only
Current Consumption
IDD5
CE=”HIGH”
4.2
Standby Current
ISTBY
CE=”LOW”
–
Maximum Receiver Input Level
PRF,MAX
-20
ASKNote2, DRate=2Kb/s,
–
Peak power level
SensitivityNote1
SIN
OOK, DRate=2Kb/s,
–
Peak power level
Data Rate
DRATE
–
LO Leakage
LLO
Measured at antenna input
–
System Start-Up Time
TSTUP
–
RF Front-End
Conversion Voltage Gain
GVRF
Matched to 50Ω
50
Noise Figure
NFRF
Matched to 50Ω
6
IF Band-Pass Filter
Filter Center Frequency
fFLT
–
IF Limiting Amplifier
IF Frequency
fIF
–
Gain
GIF
64
Bandwidth
BWLIM
–
RSSI Dynamic Range
DRRSSI
60
SAW Oscillator
Start-Up Time
TOSC,ST
–
Typ.
Max.
Unit
–
500
MHz
5.0
5.5
V
4.7
–
-10
5.2
1.0
–
mA
μA
dBm
-106
-103
-100
-97
2
–
–
50
-57
5
Kb/s
dBm
ms
55
7
60
8
dB
dB
1.8
–
MHz
1.8
70
2
70
–
76
–
80
MHz
dB
MHz
dB
–
500
μS
dBm
Notes:
1. BER=1e-3, data rate=2Kb/s.
2. Use AM 99% with square wave modulation (if limited by capabilities of signal generator).
3. Data rate selection affects choice of component values for data filter, peak detector and slicer.
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PT4317
3
Regulator Output Voltage (V)
6
Supply Current (mA)
5
4
3
2
1
0
2.5
2
1.5
1
0.5
0
2.3
3.1
3.9
4.7
5.5
2.3
3.1
Supply Voltage (V)
3.9
4.7
5.5
Supply voltage (V)
Figure 1. Supply Current vs. Supply Voltage
Figure 2. Voltage Regulator Characteristic
70
5.5
50
Supply Current (mA)
Selectivity(dBm)
60
40
30
20
10
0
-10
5
4.5
4
3.5
3
-8
-4
0
4
8
12
-40
-20
0
20
Offset Frequency(MHz)
40
60
80
100
o
Temp( C)
Figure 3. Selectivity Response for fRF = 434 MHz
Figure 4. Current Consumption vs. Temperature
-100
-101
Sensitivity(dBm)
-102
-103
-104
-105
-106
-107
-108
-109
-110
-40
-20
0
20
40
60
80
100
o
Temp( C)
Figure 5. Smith Plot of RFIN
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Figure 6. Sensitivity vs. Temperature
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PT4317
TEST BOARD LAYOUT
<Top Side>
<Bottom Side>
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PT4317
PACKAGE INFORMATION
16 Pins, SSOP, 150MIL
Symbol
A
A1
A2
b
C
D
E
E1
e
L
Min.
1.34
0.10
1.24
0.20
0.10
4.80
5.79
3.81
0.38
Nom.
1.60
0.25
5.99
3.91
0.63
-
Max.
1.75
0.25
1.52
0.30
0.25
5.00
6.19
3.98
1.27
θ
0º
-
8º
Notes:
1. Refer to JEDEC MO-137 AB.
2. Unit: mm
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PT4317
IMPORTANT NOTICE
Princeton Technology Corporation (PTC) reserves the right to make corrections, modifications, enhancements,
improvements, and other changes to its products and to discontinue any product without notice at any time.
PTC cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a PTC product. No
circuit patent licenses are implied.
Princeton Technology Corp.
2F, 233-1, Baociao Road,
Sindian, Taipei 23145, Taiwan
Tel: 886-2-66296288
Fax: 886-2-29174598
http://www.princeton.com.tw
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