Freescale Semiconductor, Inc.
Technical Data
Romeo2
MC33592/D
Rev. 0, 7/2002
PLL Tuned UHF
Receiver for Data
Transfer Applications
Pin Connections
CAFC
STROBE
RCBGAP
GNDDIG
24 23
22
21
20
19
VCC 1
18 VCCDIG
VCC 2
17 SCLK
VCCLNA 3
16 MOSI
RFIN 4
15 MISO
8
9
10
11
12
CAGC
7
XTAL2
13 DMDAT
GND
GNDSUB 6
XTAL1
14 RESETB
GNDVCO
GNDLNA 5
PFD
315MHz, 434MHz Bands
OOK Demodulation
Low Current Consumption: 5mA Typ. in Run Mode
Internal or External Strobing
Fast Wake-Up Time (1ms)
-105dBm RF Sensitivity (at 4.8kBd Data Rate)
Fully Integrated VCO
Image Cancelling Mixer
Integrated IF Bandpass Filter at 660kHz
IF Bandwidth: 300kHz
ID Byte and Tone Detection
Data Rate: 1 to 11kBd
Manchester Coded Data Clock Recovery
Fully Configurable by SPI Interface
Few External Components, no RF Adjustment
MIXOUT
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
CMIXAGC
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FEATURES
Figure 1: Simplified block diagram
Table 1: Ordering Information
Device
RF frequency/
IF filter bandwidth
Ambiant
Temperature Range
Package
MC33592FTA
434MHz / 300kHz
-40°C to +85°C
LQFP24
This document contains information on a new product under development. Motorola
reserves the right to change or discontinue this product without notice.
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© Motorola, Inc., 2002
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PIN FUNCTION DESCRIPTION
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PIN FUNCTION DESCRIPTION
2
Pin
Name
1
2
3
4
5
6
7
8
9
10
11
VCC
VCC
VCCLNA
RFIN
GNDLNA
GNDSUB
PFD
GNDVCO
GND
XTAL1
XTAL2
12
CAGC
13
14
15
16
17
18
19
20
DMDAT
RESETB
MISO
MOSI
SCLK
VCCDIG
GNDDIG
RCBGAP
21
STROBE
22
23
24
CAFC
MIXOUT
CMIXAGC
Description
5V power supply
5V power supply
5V LNA power supply
RF input
LNA ground
Ground
Access to VCO control voltage
VCO ground
Ground
Reference oscillator crystal
Reference oscillator crystal
IF AGC capacitor for OOK
Demodulated data (OOK modulation)
State Machine Reset
SPI interface I/O
SPI interface I/O
SPI interface clock
5V digital power supply
Digital ground
Reference voltage output
Strobe oscillator control
Stop/Run external control input
AFC capacitor
Mixer output
Mixer AGC capacitor
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ABSOLUTE MAXIMUM RATINGS
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ABSOLUTE MAXIMUM RATINGS
Parameter
Symbol
Value
Unit
Supply Voltage
VCC
VCCLNA
VGND - 0.3 to 5.5
V
Voltage Allowed on Each Pin
VGND - 0.3
to VCC + 0.3
V
ESD HBM Voltage Capability on Each Pin (note 1)
±2000
V
ESD MM Voltage Capability on Each Pin (note 2)
±200
V
Solder Heat Resistance Test (10 s)
260
°C
Storage Temperature
Ts
-65 to +150
°C
Junction Temperature
Tj
150
°C
Notes:
1 Human Body model, AEC-Q100-002 Rev. C.
2 Machine Model, AEC-Q100-003 Rev. E.
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RECEIVER FUNCTIONAL DESCRIPTION
RECEIVER FUNCTIONAL DESCRIPTION
The basic functionality of the ROMEO2 receiver may be seen by reference to the accompanying block
diagram (see figure 1). It is fully compatible with the TANGO3 transmitter.
The RF section comprises a mixer with image cancelling, followed by an IF band-pass filter at 660kHz, an
AGC controlled gain stage and an OOKdemodulator. The data output from the circuit may either be the data
comparator output, or, if Data Manager is enabled, the SPI port.
The local oscillator is controlled with a PLL referenced to the crystal oscillator. The received channel is defined
by the choice of the crystal frequency.
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An SPI bus permits programming the data rate, UHF frequency, ID word etc., though to accomodate
applications where no bus interface is available the circuit defaults at power-on to a standard operating mode.
Depending upon the configuration, the circuit can be either externally strobed by the STROBE input or
internally wait-and-sleep cycled to reduce the power consumption. At any time, a high level on STROBE
overrides the internal timer output and wakes up ROMEO2. When the circuit is switched into sleep mode its
current consumption is approximately 100µA. The circuit configuration which has previously been programmed is
retained.
THE LOCAL OSCILLATOR PLL
The PLL is tuned by comparing the local oscillator frequency, after suitable division, with that of the crystal
oscillator reference. The loop filter has been integrated in the IC. Practical limits upon the values of components
which may be integrated mean that the local oscillator performance may be slightly improved by using an
external PFD filter, shown in Figure 2. In this way the user may choose to have optimum performance with the
addition of external filter components. The PLL gain may be programmed by bit PG: it is recommended that this
bit be set to 1, corresponding to low loop gain.
Figure 2 : External loop filter
C1=4.7nF, C2=390pF, R=1kW
4
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COMMUNICATION PROTOCOL
COMMUNICATION PROTOCOL
MANCHESTER CODING DESCRIPTION
Manchester coding is defined as follows: data is sent during the first half-bit, complementary data is sent
during the second half-bit.
Figure 3 : Manchester coding example
0
1
0
0
1
1
0
Original data
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Manchester coded
The signal average value is constant. This allows clock recovery from the data stream itself. In order to
achieve a correct clock recovery, Manchester coded data must have a duty cycle between 48% and 52%.
PREAMBLE, ID, HEADER WORDS AND MESSAGE DESCRIPTION
The following description applies if the Data Manager is enabled (DME=1).
The ID word is a Manchester coded byte whose content has been previously loaded in the Configuration
Register 2. The complement of the ID word is recognized as an ID word. ID word is sent at the same data rate as
data.
A preamble is required:
- before ID,
- before Header if HE=1,
- before data if HE=0.
It enables AGC to settle, and clock recovery. Figure 4 defines the Preamble word. Preamble content must be
carefully defined in order not to be decoded as an ID or Header word.
Figure 4 : Preamble definition
AGC settling time
Clock recovery
ID
‘1’ NRZ > 200µs
i.e.:
2 ‘1’ NRZ at 9.6kBd,
1 ‘1’ NRZ at 4.8kBd
‘0’ Manchester
at data rate
The Header word is a 4 bit Manchester coded message ‘0110’ or its complement sent at the selected data
rate. This bit sequence and its complement must not be found in the sequence preamble and ID word.
Data must follow the Header without any delay.
Data are completed by a End-of-Message (EOM) word, consisting of 2 NRZ consecutive ones or zeroes. If the
complement of the Header word is received, output data are complemented too.
The following example shows a complete message with Preamble, ID, Header words followed by 2 data bits,
and an EOM. The preamble is placed at the beginning of both ID and Header words.
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COMMUNICATION PROTOCOL
Figure 5 : Complete message example
1 1 0 0 1 0 0 0
Preamble
0 1 1 0 1 0
Preamble
ID
Header Data
EOM
MESSAGE PROTOCOL
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If the receiver is continuously Sleep/Run cycling, the ID word has to be recognized to stay in Run mode.
Consequently, the transmitted ID burst has to be long enough to include two consecutive receiver Run cycles.
If the Strobe oscillator is enabled (SOE=1), the circuit is in Sleep mode during SR ´ TStrobe and in Run mode
during TStrobe (where TStrobe is the Strobe oscillator period and SR is the Strobe Ratio, see Table 5).
Therefore, the sleep/run cycle period is equal to (SR+1) ´ TStrobe.
If SOE=0, these timings constraints must be respected by the external control applied on pin STROBE.
Figure 6 : Complete telegram with ID detection
P+ID
P+ID
P+ID
P+ID
P+ID
P+Header
P+ID
Data
EOM
RF signal
Run
Sleep
SR ´ TStrobe
TStrobe
Sleep
Run
ID detected
P+ID = Preamble ID
= Preamble Header
P+Header
Figure 7 : Complete telegram with tone detection
Header
Tone
Data
EOM
RF signal
Sleep
Run
TStrobe
SR
Sleep
Run
´ TStrobe
ID detected
Figures 8 & 9 detail RF signals and the processing done by the receiver in several configuations.
Figure 8 : Telegrams with ID
DME=1, HE=1
Preamble ID
Preamble ID
Preamble ID
Preamble Header
Data
EOM
RF signal
ID detected
Data
SPI output
DME=1, HE=0
Preamble ID
ID
ID
ID
ID
ID
ID
ID
ID
ID
ID
ID
ID
ID
Data
EOM
RF signal
ID detected
6
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DATA MANAGER
Figure 9 : Telegrams with tone
DME=1, HE=1
Tone
Header
Data
EOM
RF signal
Tone detected
Data
SPI output
DME=1, HE=0
Tone
Data
EOM
RF signal
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Tone detected
Tone
Data
SPI output
RECEIVER START-UP DELAY
A settling time (1ms typ.) is required when entering into Wait mode. figure 10.
Figure 10 : Wait usable window
Run
Sleep
Run
Sleep
ID
ID
ID
Settling
time
ID
ID
ID
ID
ID
ID detected
DATA MANAGER
This block has five purposes:
- ID detection,
- Header recognition,
- Clock recovery,
- Output data and recovered clock on SPI port,
- End-of-Message detection.
Table 2 details some ROMEO2 features versus the bits DME and SOE values.
Table 2: ROMEO2 features versus DME and SOE
DME
Timer
ROMEO2
kept in Run mode by
Microcontroller
woken-up by
External control by
STROBE pin
Internal and external
control by STROBE pin
STROBE pin
Raw data
0
External control by
STROBE pin
STROBE pin
Message Detection
word
1
Internal and external
control by STROBE pin
ID detection
and STROBE pin
Data clock
SOE
0
0
1
1
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CLOCK GENERATOR
Table 3 details some ROMEO2 features versus DME values.
Table 3: ROMEO2 features versus DME
DME
SPI status
0
Disabled
1
Master when
RESETB=1
Data format
Output
Bitstream
No clock
Data bytes
Recovered clock
MOSI
MOSI
SCLK
CLOCK GENERATOR
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Typical crystal frequencies are:
- 9.864375MHz for 315MHz band,
- 13.580625MHz for 434MHz band.
Figure 11 : Clock generation diagram
XTAL
Reference
¸8
Phase Frequency Detector
¸ 11
IF Filter Reference Clock
& Clock Recovery
¸ 32
315MHz band
UHF Oscillator
8
434MHz band
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SERIAL INTERFACE
SERIAL INTERFACE
ROMEO2 and the microcontroller communicate through a Serial Peripheral Interface (SPI). It enables:
- the microcontroller to set and check ROMEO2 configuration,
- ROMEO2 to send the received data.
If the SPI is not used, a Power On Reset (POR) sets ROMEO2 to operate correctly in a default configuration.
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The interface is operated by the 3 following input/output pins:
- Serial Clock SCLK,
- Master Output Slave Input MOSI,
- Master Input Slave Output MISO.
The master clock is used to synchronise data movement both in and out of the device through its MOSI and
MISO lines. The master and slave devices are capable of exchanging a byte of information during a sequence of
eight clock cycles. Since SCLK is generated by the master device, this line is an input on a slave device.
The MISO line is configured as an input in a master device and as an output in a slave device. The MOSI line is
configured as an output in a master device and as an input in a slave device. The MISO and MOSI lines transfer
serial data in one direction with the most significant bit sent first. Data are captured on falling edges of SCLK.
Data are shifted out on rising edge of SCLK. When no data are output, SCLK and MOSI force a low level. Using
Motorola acronyms, this means that the clock phase and polarity control bits of the microcontroller SPI have to be
CPOL= 0 and CPHA=1.
In configuration mode, as long as a low level is applied on RESETB (see state machine on figure 14 page 12),
the microcontroller is the master node providing clock information on SCLK input, control and configuration bits
on the MOSI line. If the default configuration is not the desired one, the microcontroller (MCU) can change it by
writing into the configuration registers. The configuration registers can also be read back to check their contents.
Configuration registers cannot be addressed separately, the whole configuration has to be sent as a 3x8
bitstream. The contents are written out as a 24-bit serial data stream. Transmissions which are not multiple of 24
bits may lead to unexpected configurations. The first bit transmitted on MOSI does not change the content of the
configuration registers. Note that a low level applied on RESETB does not affect the configuration register
content.
When RESETB is set to a high level, if Data Manager is enabled (DME=1), ROMEO2 becomes master and
sends received data on the MOSI line and the recovered clock on SCLK. It is then recommended that the MCU
SPI is set as slave. If the data received does not fit in an entire number of bytes, the data manager will fill the last
byte. If the data received constitute an whole number of bytes, the data manager may generate and send an
extra byte whose content is irrelevant. If DME=0, the SPI is disabled. Raw data is sent on the MOSI line.
When ROMEO2 SPI is changed from master (run mode) to slave (configuration mode) or from slave to
master, it is recommended that the MCU SPI is set as slave before the mode transition.
At power-on, the POR resets the internal registers. This defines the receiver default configuration (see gray
rows on tables 4, 7 & 8). In this configuration, the SPI is disabled and ROMEO2 sends raw data on the MOSI line.
This default configuration enables the circuit to operate as a standalone receiver without any external control.
After POR, RESETB forces a low level. Therefore an external pull-up resistor should be used in order to avoid
entering configuration mode.
Figure 12 : Writing into configuration registers
ROMEO2
MCU (master)
0
CR1
CR2
CR3
MOSI line
SCLK line
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CONFIGURATION REGISTERS
Figure 13 : Reading configuration registers
ROMEO2
MCU (master)
1
Don’t care
Don’t care
Don’t care
MOSI line
SCLK line
1
CR1
MISO line
ROMEO2
MCU (master)
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CR3
CR2
CONFIGURATION REGISTERS
Table 4 describes the Configuration Register 1 (CR1).
Bit name
Reset value
Table 4: Configuration Register 1
bit 7
bit 6
bit 5
bit 4
bit 3
R/W
CF
MOD SOE
SR1
1
1
0
1
0
bit 2
SR0
1
bit 1
DME
0
bit 0
HE
0
- R/W controls the 3 registers access (read or write):
0 = Write CR1, CR2 ,CR3,
1 = Read CR1, CR2, CR3.
- CF defines the Carrier Frequency as shown onTable 5.
Table 5: Carrier Frequency selection
CF
Selected Frequency
0
315MHz
1
434MHz
- MOD sets the data Modulation type:
0 = On/Off Keying (OOK) modulation,
1 = Not allowed.
- SOE enables the Strobe Oscillator:
0 = Disabled,
1 = Enabled,
Whatever SOE value has been programmed, a high level on STROBE sets the circuit into run mode.
- SR0/SR1 define the Strobe Ratio (SR) as shown on Table 6. SR is the ratio Sleep time over Run time and
Run time=TStrobe (where TStrobe is the Strobe oscillator period).
Table 6: Strobe Ratio selection
SR1
SR0
Strobe Ratio
0
0
3
0
1
7
1
0
15
1
1
31
10
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CONFIGURATION REGISTERS
- DME enables the Data Manager:
0 = Disabled,
1 = Enabled.
Data are output on MOSI and the associated clock on SCLK.
- HE defines if a Header word is present (the bit HE is only active if DME=1):
0 = No header,
1 = Header.
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Configuration Register 2 (CR2) defines the Identifier (ID) word content. The bits will be Manchester coded.
Bit name
Reset value
Table 7: Configuration Register 2
bit 7
bit 6
bit 5
bit 4
bit 3
ID7
ID6
ID5
ID4
ID3
0
0
0
0
0
bit 2
ID2
0
bit 1
ID1
0
bit 0
ID0
0
bit 2
0
bit 1
0
bit 0
0
Table 8 describes the Configuration Register 3 (CR3).
Bit name
Reset value
Table 8: Configuration Register 3
bit 7
bit 6
bit 5
bit 4
bit 3
DR1
DR0
MG
MS
PG
1
0
0
0
0
- DR0/DR1 define the Data Rate (before Manchester coding) as shown onTable 9.
Table 9: Data Rate selection
DR1
DR0
Selected Ratio
0
0
1.0 - 1.4 kBd
0
1
2 - 2.7 kBd
1
0
4 - 5.3 kBd
1
1
8.6 - 10.6 kBd
- MG sets the mixer gain:
0 = Normal,
1 = -17dB (typical).
- MS switches the MIXOUT pin:
0 = To the mixer output,
1 = To the IF input.
MG
0
0
1
1
Table 10: Mixer and MIXOUTconfiguration
MS
Mixer Gain
MIXOUT
0
Normal
Mixer output
1
Normal
IF input
0
Reduced
Mixer output
1
Forbidden, mixer test mode only
The combination MG=1, MS=1 is forbidden in any application. It configures the receiver in a test mode where
the mixer runs at fVCO/4.
- PG sets the phase comparator gain (see “The local oscillator PLL” chapter, page 4):
0 = High gain mode,
1 = Low gain mode.
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STATE MACHINES
STATE MACHINES
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AFTER POR RESET STATE MACHINE
There are 3 different modes for the receiver.
Sleep mode corresponds to the low power consumption mode:
- if SOE=0, the whole receiver is shutdown,
- if SOE=1, the strobe oscillator remains active.
Configuration mode is used for writing or reading the internal registers. In this mode, the SPI is slave and the
receiver is enabled. The crystal oscillator is running and generates the clock for the SPI. This implies that before
the circuit is in sleep mode, a delay corresponding to the crystal oscillator wake-up time must be inserted
between the falling edge on RESETB and the start of the transmission on the SPI lines. The local oscillator is
running as well. This means that demodulated data can be read on DMDAT but are not sent by the SPI.
In Run mode, the receiver is enabled (crystal and local oscillators are running). It is either waiting for an RF
telegram or receiving one.
Figure 14 details the state machine after Power On Reset (POR). The state machine is synchronized by a
sampling clock at 615kHz (sampling period Ts=1.6µs), derivated from the crystal oscillator. The transition time
between state 1 and states 2 or 6 is less than 3 ´ Ts.
After POR, the circuit is in state 0 and configuration registers’ content is set to the reset value. This enables to
use ROMEO2 in a standalone configuration without any external control.
As long as a low level is applied on RESETB, the circuit stays in state 1. This configuration mode enables to write
or read the internal registers through the SPI interface.
Figure 14 : After POR state machine
Strobe Counter=SR
OR STROBE=1
Power-On Reset
State 0
Sleep mode
SPI disabled
State 0b
Run mode
Raw data on MOSI
SPI disabled
Strobe Counter ¹ SR
AND STROBE=0
RESETB=1
AND DME=0
RESETB=0
State 1
Configuration mode
SPI active and slave
RESETB=1
RESETB=1
AND DME=1 AND DME=1
AND SOE=1 AND SOE=0
SPI disabled
SPI slave
State 2, see figure
12
State 6, see figure
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SPI master
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STATE MACHINES
STATE MACHINE WITH STROBE OSCILLATOR CONTROL
Figure 15 details the state machine when the strobe oscillator is enabled (SOE=1).
Figure 15 : State machine with strobe oscillator control
SPI master
State 2
Sleep mode
Reset and Start Strobe Counter
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Strobe Counter=SR
OR STROBE=1
Strobe Counter ¹ SR
AND STROBE pin released
State 3
Run mode
Waiting for ID word
ID detected
AND HE=1
Time-out
ID detected
AND HE=0
State 4
Run mode
Reset and start Timer
Waiting for Header
Header received
State 5
Run mode
Output data & clock
Waiting for End of Message
EOM received
State 2:
The circuit is in Sleep mode, except for the Strobe oscillator and the Strobe counter.
State 3:
The circuit is waiting for a valid ID word. If ID or its complement is detected, the state machine advances to state
4. If not, it will go back into sleep mode (state 2) at the end of the Strobe period.
State 4:
ID or its complement has been detected, Data Manager is waiting for Header or its complement. Time-out
counter is running. This counter will count up to 66 (± 1) times the strobe oscillator period (TStrobe).
State 5:
If Header has been received, data and clock signals are output on the SPI port until End of Message indicates the
data sequence end. If the complement of Header has been received, output data are complemented too.
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STATE MACHINES
For all states:
At any time, a low level applied on RESETB during more than one Ts forces the state machine to state 1. When
the transition condition from one state to the next one is fulfilled, the transition time is one Ts (except for reaching
state 2). The transition time to state 2 is 2 ´ Ts (+ duration of the dummy byte if it is shifted out, only for transition
coming from state 5).
STATE MACHINE WITH STROBE PIN CONTROL
Figure 16 details the state machine when the strobe oscillator is disabled (SOE=0).
Figure 16 : State machine with STROBE pin control
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State 6
Sleep mode
SPI master
STROBE=1
STROBE=0
State 7
Run mode
Waiting for ID word
ID detected
STROBE=0
State 8
Run mode
Send an ID word
HE=1
STROBE=0
HE=0
State 9
Run mode
Waiting for Header
Header received
STROBE=0
State 10
Run mode
Output data & clock
EOM received
STROBE=0
14
State 11
Run mode
Output data
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STROBE OSCILLATOR
State 6:
Programming SOE=0 sets ROMEO2 to state 6. The circuit is in Sleep mode.
State 7:
A high level applied on STROBE sets the circuit into state 7. If an ID or its complement is detected, the state
machine advances to state 8. If not, it will stay in state 7 as long as STROBE is high.
State 8:
After ID or its complement detection, ID byte is sent to the microcontroller on MOSI line at 310kBd. This warns
the microcontroller that data are received which means that an high level has to be maintained on STROBE. At
any time a low level applied on STROBE sets the circuit into state 6.
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State 9:
If Header or its complement is detected, the state machine advances to state 10. If not, it will stay in state 9 as
long as STROBE is high.
State 10:
If Header has been received, data and clock signals are output on the SPI port. If the complement of Header has
been received, output data are complemented too. At any time a low level applied on STROBE sets the circuit
into state 6, after the current byte is fully transmitted.
State 11:
If data are received after a End of Message they are output on the MOSI pin without clock recovery.
For all states:
At any time, a low level applied on RESETB for more than one Ts forces the state machine to state 1. When the
transition condition from one state to the next one is fulfilled, the transition time is one Ts except reaching state 6.
The transition time for reaching state 6 is 2 ´ Ts (+ time needed to shift out a full byte if STROBE pin is forced to
low when in state 10).
STROBE OSCILLATOR
The Strobe Oscillator is a relaxation oscillator in which an external capacitor C5 is charged by an external
resistance R2 (refer to figure 17 and table 11). When a threshold is reached or exceeded C5 is discharged and
the cycle restarts. The period is: TStrobe=0.12 ´ R2 ´ C5.
The circuit may be forced into states 0b, 3, 7 etc. (see State Machine Diagrams) by setting the STROBE pin to
VCC. As VCC is above the oscillator threshold voltage referred to in the previous paragraph, the condition in which
the STROBE pin is set to VCC is internally detected and the oscillator pull-down circuitry disabled to limit the
current which must be supplied.
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ELECTRICAL CHARACTERISTICS
.
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
Parameter
Test Conditions, Comments
Freescale Semiconductor, Inc...
1
Limits
Min.
Typ.
Max.
Unit
General Parameters
1.1
Mean Supply Current
315 & 434MHz bands, Strobe Ratio=7,
PG=0, see note 1
-
815
1100
µA
1.3
Supply Current in Run
& Configuration Modes
315 & 434MHz bands, PG=0
-
5.7
7.4
mA
Strobe oscillator enabled
-
115
250
µA
Strobe oscillator disabled
-
90
200
µA
1.5
1.6
Supply Current in Sleep Mode
1.7
Supply Current in Run
& Configuration Modes
315 & 434MHz bands, PG=1
-
5.4
7.0
mA
1.9
Sleep Mode to Run Mode Delay
Circuit ready to receive,
OOK modulation
-
1.0
1.8
ms
Measured between
falling edge on STROBE
and supply current reduced to 10%
-
0.1
-
ms
1.11 Run Mode to Sleep Mode Delay
Note 1: If IRun and ISleep are the supply currents in Run and Sleep modes and SR is the Strobe Oscillator Ratio,
the Mean Supply Current IMean is given by: IMean=(IRun + SR ´ ISleep) / (SR + 1).
16
MC33592 Technical Data
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Freescale Semiconductor, Inc.
ELECTRICAL CHARACTERISTICS
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
Parameter
Limits
Min.
Typ.
Max.
Unit
RF Parameters
General and Front End parameters assume a 50W resistor in parallel with the D.U.T. except where the use
of a matching network is specified.
2
Freescale Semiconductor, Inc...
Test Conditions, Comments
2.1.1
Sensitivity in OOK
at nominal transmitter
center frequency
DME=0, with matching network,
see notes 2, 3, 5, 6
-
-105
-96
dBm
2.1.2
""
DME=1, with matching network,
see notes 2, 4, 5, 6
-
-103
-94
dBm
2.1.3
""
DME=0, see notes 2, 3, 6
-
-96
-87
dBm
2.1.4
""
DME=1, see notes 2, 4, 6
-
-94
-85
dBm
DME=0, with matching network,
see notes 2, 3, 5, 6
-
-105
-98
dBm
2.2.1
Sensitivity in OOK
at nominal transmitter
center frequency
Operating temperature range
-20°C to +85°C
2.2.2
""
DME=1, with matching network,
see notes 2, 4, 5, 6
-
-103
-96
dBm
2.2.3
""
DME=0, see notes 2, 3, 6
-
-96
-89
dBm
2.2.4
""
DME=1, see notes 2, 4, 6
-
-94
-87
dBm
315MHz band
17
25
-
dB
434MHz band
20
29
-
dB
315 MHz band,
measured at MIXOUT, min. value
for 2 pairs of frequencies (MHz):
(340.00, 365.00), (500.00, 685.00)
-
-17
-
dBm
434MHz band,
measured at MIXOUT, min. value
for 2 pairs of frequencies (MHz):
(455.00, 476.08), (550.00, 666.08)
-
-19
-
dBm
OOK modulation,
TX modulation depth: 97.5%
-
-14
-
dBm
2.9
2.10
Image Frequency Rejection
2.12
IP3
2.13
2.15
Max. Detectable Input Signal
Level of a NRZ 1
MOTOROLA
MC33592 Technical Data
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Freescale Semiconductor, Inc.
ELECTRICAL CHARACTERISTICS
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
Parameter
2.27
Freescale Semiconductor, Inc...
2.28
2.29
2.39
2.43
2.44
2.46
2.47
Test Conditions, Comments
Out-of-Band Jammer
desensitization for
OOK modulation
434MHz band, PG=1,
sensitivity reduced by 6dB
In-Band Jammer desensitization
434MHz band
sensitivity reduced by 6dB
Input Impedance: // Resistance
Input Impedance: // Capacitance
Limits
Unit
Min.
Typ.
Max.
CW jammer at RF ±500kHz,
see note 4
-
16
-
dBc
CW jammer at RF ±1MHz,
see note 4
-
24
-
dBc
CW jammer at RF ±2MHz,
see note 4
-
33
-
dBc
OOK modulation,
CW jammer at RF ±50kHz, see note 4
-
-10
-
dBc
315MHz, level on RFIN £ -50dBm
-
1.1
-
kW
434MHz, level on RFIN £ -50dBm
-
1.1
-
kW
315MHz band
-
1.4
-
pF
434MHz band
-
1.4
-
pF
2.51
Mixer Conversion Gain
315 & 434MHz bands,
from RFIN to MIXOUT
-
48
-
dB
2.53
Mixer Gain Reduction
315 & 434MHz bands,
when setting MG=1
-
18
-
dB
2.55 Mixer Input Gain reduced by 1dB
315 & 434MHz bands
-
-49
-
dBm
2.57
Mixer AGC Settling Time
RF rise time < 400ns,
10 to 90% rise time
-
4
-
µs
2.58
Mixer AGC Gain Decay Rate
-
5
-
dB/ms
18
MC33592 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc.
ELECTRICAL CHARACTERISTICS
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
2.59
Parameter
Test Conditions, Comments
Local Oscillator Leakage
315 & 434MHz bands,
at matching network input, see note 5
Limits
Min.
Typ.
Max.
-
-102
-70
Unit
dBm
Note 2: OOK Sensitivity vs Temperature characteristic (shown for parameters 2.1.4 & 2.2.4)
Freescale Semiconductor, Inc...
Temperature (°C)
-40
-25
-10
5
20
35
50
65
80
-80
-81
-82
-83
-84
-85
-86
Typ.
Max
-87
-88
-89
-90
-91
-92
-93
-94
-95
Parameters 2.1.1 to 2.1.3 and 2.2.1 to 2.2.3 characteristics vs temperature are similar.
MOTOROLA
MC33592 Technical Data
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Freescale Semiconductor, Inc.
ELECTRICAL CHARACTERISTICS
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
Parameter
Test Conditions, Comments
Limits
Min.
Typ.
Max.
Unit
Freescale Semiconductor, Inc...
Note 3: Sensitivity measurement method with Data Manager disabled (DME=0)
A continuous Manchester coded 0 sequence (4.8kBd, OOK modulation depth: 100%, 50% duty cycle) is applied
at RFIN. The mean value of the frequency of the output signal on MOSI is measured over 200 cycles. The
sensitivity is defined as the lowest input level during an NRZ one corresponding to a mean output frequency
deviation lower than 5% of the expected data rate.
Note 4: Sensitivity measurement method with Data Manager enabled (DME=1, HE=0)
A complete telegram (4.8kBd, OOK modulation depth: 100%, 50% duty cycle) including preamble, ID word and
data (80 random bits without Header) is applied at RFIN. The sensitivity is defined as the lowest input level
during an NRZ one necessary to achieve 0 Bit Error Rate (BER).
Note 5: 50W matching networks
434MHz band: C1=1.5pF, C2=100pF, L1=68nH.
Tolerances: +/-10% for capacitances; +/-2% for inductor
Note 6: Sensitivity measurement conditions
* OOK at 4.8kBd (50% duty cycle)
* 315MHz & 434MHz bands (300kHz IF bandwidth)
* Performances include receiver crystal tolerance of +/-80ppm over temperature range i.e. +/-35kHz @ 434MHz
20
MC33592 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc.
ELECTRICAL CHARACTERISTICS
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
Parameter
Limits
Min.
Typ.
Max.
Unit
IF filter, IF Amplifier, FM to AM Converter and Envelope Detector
The IF filter operates at approximately 660kHz, with a 300kHz bandwidth.
3
Freescale Semiconductor, Inc...
Test Conditions, Comments
3.1
IF High Cut Off Frequency
at -3dB
IF bandwidth: 300kHz
755
810
-
kHz
3.3
IF Low Cut Off Frequency
at -3dB
IF bandwidth: 300kHz
-
520
565
kHz
3.5
IF Cut Off Low Freq. at -30dB
-
400
-
kHz
3.6
IF Cut Off High Freq. at -30dB
-
1100
-
kHz
3.9
IF Bandwidth at -3dB
IF bandwidth: 300kHz
-
300
360
kHz
3.11
Total filter gain variation
within -3dB Bandwidth
IF bandwidth: 300kHz
-3
-
3
dB
3.13
IF Amplifier Gain
From MIXOUT to DMDAT
-
55
-
dB
3.14
IF AGC Dynamic Range
-
55
-
dB
3.15
IF AGC Gain Decay Rate
-
2.5
-
dB/ms
3.16
IF Amplifier AGC Settling Time
-
75
200
µs
3.17
Detector Output
Signal Amplitude
-
260
-
mVpk-
MOTOROLA
IF bandwidth: 300kHz
OOK modulation
OOK modulation, measured at DMDAT
MC33592 Technical Data
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pk
21
Freescale Semiconductor, Inc.
ELECTRICAL CHARACTERISTICS
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
Parameter
Test Conditions, Comments
Unit
Min.
Typ.
Max.
-
-
200
W
OOK modulation, DME=0
1
-
11
kHz
DR1=0, DR0=0, 1200 bauds
51
73
102
µs
DR1=0, DR0=1, 2400 bauds
30
42
57
µs
DR1=1, DR0=0, 4800 bauds
19
25
34
µs
5.5
DR1=1, DR0=1, 9600 bauds
12
16
22
µs
5.6
DR1=0, DR0=0
1.0
-
1.4
kBd
DR1=0, DR0=1
2
-
2.7
kBd
DR1=1, DR0=0
4
-
5.3
kBd
DR1=1, DR0=1
8.6
-
10.6
kBd
Pins MOSI, SCLK, RESETB
0
-
0.3 ´
VCC
V
0.7 ´
VCC
-
VCC
V
-
2
-
µA
0
0.02
0.2 ´
VCC
V
0.8 ´
VCC
4.97
VCC
V
-
-
100
ns
0
-
0.5
V
4.4
-
VCC
V
4
4.1
Freescale Semiconductor, Inc...
Limits
PLL Divider & Crystal Oscillator
Maximum Crystal
Series Resistance
5
5.1
Data Filter & Slicer, Data Manager, SPI
Data Frequency
5.2
5.3
5.4
5.7
5.8
Low pass filter delay
2nd order Butterworth response
Data Rate Range
for Clock Recovery
5.9
5.10
Input Low Voltage
5.11
Input High Voltage
5.13
Input Pull Down Current
5.14
Output Low Voltage
5.15
Output High Voltage
Pins MOSI, SCLK, RESETB, VIN=VCC
Pins MOSI, MISO, SCLK,
|ILOAD| =10µA
Pins MOSI, MISO, SCLK, CLOAD =
5pF,
from 10% to 90% of the output swing
5.16
Fall/Rise Time
5.17
Input Low Voltage
5.18
Input High Voltage
5.19
Input Pull Down Current
Pin STROBE used as digital input,
VIN=VCC
-
-
50
µA
5.20
SPI data rate
On MOSI, MISO & SCLK,
SPI master or slave,
see note 7
-
-
310
kBd
22
Pin STROBE used as digital input
MC33592 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc.
ELECTRICAL CHARACTERISTICS
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
Freescale Semiconductor, Inc...
Parameter
Test Conditions, Comments
5.21
SPI interface source current
VOH=0.8 ´ VCC
5.22
SPI interface sink current
VOL=0.2 ´ VCC
Limits
Unit
Min.
Typ.
Max.
60
170
-
µA
60
220
-
µA
MOSI, MISO, SCLK pins
Note 7: As well as the state machine, the SPI interface is synchronized by a sampling clock at 615kHz derivated
from the crystal oscillator. The maximum speed is then half this synchronization clock.
MOTOROLA
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Freescale Semiconductor, Inc.
ELECTRICAL CHARACTERISTICS
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, VCC=[4.5V;5.5V], operating temperature range TA=[-40°C;+85°C]. Values refer to
the circuit in recommended in the application schematic (see figure 17), unless otherwise specified. Typical
values reflect average measurement at VCC=5V, TA=25°C, using MC33592.
Parameter
Freescale Semiconductor, Inc...
6
Limits
Min.
Typ.
Max.
2
3.8
87
Unit
Strobe Oscillator (SOE=1)
6.1
Strobe Oscillator Period
(TStrobe) Range
6.9
External Capacitor (C5)
6.10
External Resistor (R2)
6.2
Strobe Oscillator
Period Accuracy
6.3
Strobe Oscillator Period
Temperature Coefficient
6.4
Strobe Oscillator Period
Supply Voltage Coefficient
6.5
Sink Output Resistance
6.7
High Threshold Voltage
6.8
Low Threshold Voltage
24
Test Conditions, Comments
TStrobe=0.12 ´ R2 ´ C5,
see figure 17
TJ=25°C, VCC=5V,
external components R2 & C5 fixed
ms
-
68
330
nF
-
470
2200
kW
-5
-
5
%
-
0.05
-
%/°C
-
0.2
-
-
-
6
-
kW
-
1.0
-
V
-
0.45
-
V
(DTStrobe/TStrobe)/(DVCC/VCC)
Pin STROBE
MC33592 Technical Data
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Freescale Semiconductor, Inc.
APPLICATION SCHEMATIC
APPLICATION SCHEMATIC
Freescale Semiconductor, Inc...
Figure 17 : Application schematic
MC33592
Component description: see tables 11, 12.
MOTOROLA
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Freescale Semiconductor, Inc.
APPLICATION SCHEMATIC
Component
Q
R1
R2
C1
C2
Freescale Semiconductor, Inc...
C3
C4
C5
C6
C7
C8
C9
Table 11: Component description
Function
Value
315MHz band: 9.864375
Reference oscillator crystal
434MHz band: 13.580625
Current reference resistor
180 ± 1%
Strobe oscillator resistor
470
Crystal load capacitor
10
- OOK modulation 100 ± 10%
IF amplifier AGC capacitor
AFC capacitor
100 ± 10%
Mixer AGC capacitor
10 ± 10%
Strobe oscillator capacitor
68
100
Power supply
100
decoupling capacitor
1
Crystal DC
10
decoupling capacitor
Unit
MHz
MHz
kW
kW
pF
nF
pF
nF
nF
nF
pF
nF
nF
R2 and C5 values correspond to a strobe oscillator period TStrobe=3.8ms.
Exemples of crystal references are given below
Table 12: Typical crystal characteristics (SMD package)
NDK LN-G102-952
NDK LN-G102-877
Parameter
(for 315MHz)
(for 434MHz)
Crystal frequency
9.864375
13.580625
Load capacitance
12
12
Motional capacitance
3.71
4.81
Static capacitance
1.22
1.36
Max loss resistance
100
50
26
MC33592 Technical Data
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Unit
MHz
pF
fF
pF
W
MOTOROLA
Freescale Semiconductor, Inc.
CASE OUTLINE DIMENSIONS
Freescale Semiconductor, Inc...
CASE OUTLINE DIMENSIONS
MOTOROLA
MC33592 Technical Data
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JAPAN:
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81-3-3440-3569
Freescale Semiconductor, Inc...
ASIA/PACIFIC:
Information in this document is provided solely to enable system and software
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MC33592/D
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