ETC NRF902

PRELIMINARY PRODUCT SPECIFICATION
nRF902
Single chip 868 MHz Transmitter
FEATURES
APPLICATIONS
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True single chip FSK/ASK transmitter in
a small 8-pin package
Adjustable output power up to +10dBm
FSK data rate up to 50kbits/s
Very few external components
On-chip frequency synthesiser gives
improved frequency stability compared to
SAW solutions
Wide power supply range: 2.4 to 3.6 V
Low supply current, typical 9mA
@ -10dBm output power
Power Down and Clock modes makes
power saving easy
Reference Clock output pin for
microcontroller
Automatic Meter Reading
Keyless entry
Wireless data communication
Alarm and security systems
Home Automation
Remote control
Surveillance
Automotive
Telemetry
Toys
GENERAL DESCRIPTION
nRF902 is a single-chip transmitter for the 868 MHz ISM band, designed to comply
with the ETSI specification I-ETS 300 220. Using nRF902 both FSK and ASK
modulation is possible. The transmitter consists of a fully integrated frequency
synthesiser, a power amplifier, a crystal oscillator and a modulator. Few external
components are required: a 13.567 MHz crystal, two resistors and some decoupling
capacitors. Due to the use of the crystal-oscillator stabilised frequency synthesiser,
frequency drift is much lower than in comparable SAW-resonator based solutions.
Output power is easily programmable by use of an external resistor. Current
consumption is very low, only 9 mA at an output power of –10dBm. Built-in Clock
and Power Down modes makes power saving and duty-cycling easily realisable.
QUICK REFERENCE DATA
Parameter
Value
Unit
2.4
10
50
10
9
200
<10
V
dBm
kbit/s
kbit/s
mA
µA
nΑ
Minimum supply voltage
Maximum output power
Maximum FSK data rate
Maximum ASK data rate
Supply current FSK transmitter @ -10dBm output power
Supply current in Clock mode
Supply current in Power Down mode
Table 1. nRF902 quick reference data
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
BLOCK DIAGRAM
Crystal
Oscillator
Clock
Divider
xtal
1 /8
FSK
XO8
Frequency synthesizer
Phase
Detector
Loop
Filter
VCO
Power
A m p lifier
ant1
ant2
Prescaler
1/64
REXT
Figure 1. nRF902 block diagram
PIN FUNCTIONS
Pin
Name
Pin function
Description
1
2
3
4
5
6
7
8
xtal
REXT
XO8
VDD
FSK
ant2
ant1
VSS
Input
Input
Output
Input
Input
Power/Output
Power/Output
Power
Crystal pin / Power Up
Power adjust / Clock Mode / ASK modulation digital input
Reference Clock Output (Crystal Frequency / 8)
Positive Supply (2.4 - 3.6V)
Digital Data Input
Antenna output 1
Antenna output 2
Ground (0V)
Table 2. nRF902 pin functions
PIN ASSIGNMENT
8
VSS
2
7
ant1
XO8
3
6
ant2
VDD
4
5
FSK
xtal
1
REXT
nRF902
Figure 2. nRF902 pin assignment
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
ELECTRICAL SPECIFICATIONS
Conditions: VDD = +3V, VSS = 0V, TA = - 40ºC to + 85ºC
Symbol Parameter (condition)
fXTAL
VDD
Tamb
PRF
IDD
IDD
Operating conditions
Transmit frequency
Crystal frequency
Supply voltage
Operating temperature
Maximum Output Power
Supply current CLOCK Mode
Supply current POWER DOWN Mode
∆f
RFSK
IDD
IDD
FSK modulation
Frequency deviation
FSK data rate
Supply current @ 10dBm output power
Supply current @ -10dBm output power
RASK
PRF1
PRF0
IDD
IDD
ASK modulation
ASK data rate
Transmitted power at data = ‘1’
Transmitted power at data = ‘0’
Supply current @ 10dBm output power
Supply current @ -50dBm output power
VIH
VIL
VOH
VOL
FSK input pin
HIGH level input voltage
LOW level input voltage
HIGH level output voltage
LOW level output voltage
fTX
Notes
Min.
1)
1)
868
13.563
2.4
- 40
3)
2)
10
3)
3)
Typ.
Max.
Units
200
10
870
13.593
3.6
+ 85
10
300
100
MHz
MHz
V
°C
dBm
µA
nA
30
9
30
50
37
17
kHz
kbit/s
mA
mA
30
200
10
10
-50
37
300
kbit/s
dBm
dBm
mA
uA
VDD
0.3
VDD
0.3
V
V
V
V
20
0
3)
3)
VDD - 0.5
Vss
VDD - 0.5
Vss
NOTES:
1) The crystal frequency may be altered to produce any desired frequency within the 868MHz to 870MHz band.
2) Measured with no load on XO8 output pin.
3) Antenna load impedance = 400 Ω.
Table 3. nRF902 electrical specifications
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
PACKAGE OUTLINE
nRF902, uses the SOIC 8 package. Dimensions are in mm.
8 7 6 5
E
H
1 2 3 4
D
α
A1 A
L
e
Package Type
SOIC 8
b
Min
Max
D
4.80
4.98
E
3.81
3.99
H
5.84
6.20
A
1.55
1.73
A1
0.127
0.250
e
1.27
b
0.35
0.49
L
0.41
0.89
Copl.
0.25
α
0°
8°
Figure 3. Package outline.
Absolute Maximum Ratings
Supply voltages
VDD ............................. - 0.3V to + 6V
VSS ................................................ 0V
Input voltage
VI ...................... - 0.3V to VDD + 0.3V
Total Power Dissipation
PD (TA=85°C)........................... 220mW
Temperatures
Operating Temperature…. - 40°C to + 85°C
Storage Temperature…... - 40°C to + 125°C
Output voltage
VO ..................... - 0.3V to VDD + 0.3V
Note: Stress exceeding one or more of the limiting values may cause permanent
damage to the device.
ATTENTION!
Electrostatic Sensitive Device
Observe Precaution for handling.
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
IMPORTANT TIMING DATA
Timing information
The timing information for the different operations is summarised in Table 4.
(TX is Transmit mode, Clk is Clock mode, Pwr_Dn is Power Down Mode.)
Change of Mode
Pwr_Dn è TX
Clk è TX
Max Delay
2ms
30us
Table 4 Switching times for nRF902
Switching between Power Down Mode and Transmit-mode.
The maximum time from Power Down mode until the synthesised frequency is stable
and data can be transmitted is seen in Figure 4.
VDD
xtal
FSK
2ms
ms
0
2
4
Figure 4. Timing diagram when going from Power Down mode to Transmit-mode
Switching between Clock Mode and Transmit-mode.
The maximum time from Clock mode until the synthesised frequency is stable and
data can be transmitted is seen in Figure 5.
VDD
REXT
FSK
30us
us
0
30
Figure 5. Timing diagram when going from Clock mode to Transmit-mode
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
APPLICATION INFORMATION
FSK Transmit mode
FSK modulation is realised by feeding the modulating data to the digital FSK input
pin (see Figure 6).
X1 13.567MHz
R1
VDD
xtal
1
R2
VDD
REXT
Clock
Output
XO8
VDD
VDD
8
nRF902
7
2
6
3
5
4
VSS
ant1
ant2
Matching Network/
Antenna
Data
Input
FSK
C
2
C
1
Figure 6. FSK transmitter in FSK Transmit mode
In applications where high data rate and low spectrum bandwidth is required an
external varactor may be used to modulate the crystal. For optimum bandwidth usage
a low pass filter should be used to shape the input bit stream, (see Figure 7).
Data
Input
X1 13.567MHz
R1
VDD
xtal
nRF902
R2
VDD
REXT
Clock
Output
XO8
VDD
VDD
C1
8
1
2
7
3
6
4
5
VSS
ant1
Matching Network/
Antenna
ant2
FSK
C2
Figure 7. FSK transmitter in FSK Transmit mode for low spectral bandwidth
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
ASK modulation.
ASK modulation can be realised by using the REXT pin (see Figure 8). When R2 is
connected to VDD, the chip transmits a carrier. When the bias resistor is connected to
VSS then the internal output power amplifier is turned off. These two situations
represent logic ‘1’ and logic ‘0’ in an ASK system. When ASK modulation is used,
the FSK pin must be connected to VDD.
X1 13.567MHz
R1
VDD
xtal
Data
Input
1
R2
REXT
Clock
Output
XO8
VDD
VDD
C1
8
nRF902
7
2
6
3
5
4
VSS
ant1
Matching Network/
Antenna
ant2
VDD
FSK
C2
Figure 8. FSK transmitter in ASK Transmit mode
Antenna output
The “ant” output pins provide a balanced RF output to the antenna. The pins must
have a DC path to VDD, either via a RF choke or via the centre point in a loop antenna.
The load impedance seen between the ant1/ant2 outputs should be in the range 200700Ω. A load impedance of 400Ω is recommended if maximum output power
(10dBm) is needed. Lower load impedance (for instance 50 Ω) can be obtained by
fitting a simple matching network or a RF transformer (balun). The 50 Ω load can
also be connected directly between the ant1/ant2 pins, but this will result in higher
current consumption for a given output power to the antenna.
Note: Application notes of antenna layout solutions with matching networks will soon
be available on our website: http://www.nvlsi.no.
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
Power Down mode
Power Down mode is used to achieve very low current consumption. Effectively the
chip is disabled with minimal leakage current consumption, typically less than 10nA.
Operating in this mode when not transmitting data, i.e. low duty cycle systems can
significantly increase battery lifetime.
The resistor R1 connected from the crystal pin towards VDD supplies the crystal
oscillator with bias current (see Figure 9). When this resistor is connected to VSS or
left open, the chip enters Power Down mode. As shown in Figure 9 the resistor R1 is
connected to the “Power Down” terminal, this can be controlled by a micro-controller,
hence eliminating the need to switch off the power supply to the chip when not
transmitting. Start-up time when switching from Power Down mode to Transmit
mode is approximately 2 ms.
X1 13.567MHz
R1
Power
Down
xtal
1
R2
VDD
REXT
Clock
Output
XO8
VDD
VDD
C1
8
nRF902
7
2
6
3
5
4
VSS
ant1
Matching Network/
Antenna
ant2
Data
Input
FSK
C2
Figure 9. FSK transmitter in Power Down mode
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
Clock mode
Clock mode is available so that an external microprocessor may have a reference
signal without the cost of a second crystal. In Clock mode, the crystal oscillator and
reference clock outputs are operating, while the rest of the transmitter is disabled. The
reference signal from the internal crystal oscillator is divided by 8 by use of a
prescaler, this signal is available at the XO8 pin.
Clock mode may be set by connecting the power adjusting resistor R2 to ground or by
leaving it open (see Figure 10). Current consumption in Clock mode is typically 200
µA when no load is applied at the XO8 clock output pin. If a capacitive load is
applied at the XO8 output, then current consumption in Clock mode will increase.
Start-up time when switching between Clock mode and Transmit mode is extremely
fast, typically 30µs.
X1 13.567MHz
R1
VDD
xtal
nRF902
R2
REXT
Clock
Output
XO8
VDD
VDD
C1
8
1
7
2
6
3
5
4
VSS
ant1
Matching Network/
Antenna
ant2
Data
Input
FSK
C2
Figure 10. FSK transmitter in Clock mode
XO8 Clock Output Pin Capacitance
The frequency of the clock signal is 1/8th of the crystal frequency i.e. a crystal
frequency of 13.567 MHz will result in an output clock frequency of 1.695 MHz. The
XO8 output signal will be present in Transmit mode and Clock mode. In Power Down
mode the XO8 signal will be a logic “0”.
The capacitive load at the XO8 pin will affect current consumption in Clock mode. If
the pin is left open the current consumption will typically be 200uA. Adding a
capacitive load, such as microcontroller load [CML] to the XO8 pin will result in an
increase in the current consumption, the increase ∆I is given as:
∆I = fXO8 ⋅VDD⋅ CML
Example
With a capacitive load of CML = 5pF, using VDD=3.0 V and a 13.567 MHz crystal,
the current increase ∆I becomes :
∆I = fXO8 ⋅VDD⋅ CML = ((13 .567 MHz) / 8) ⋅ 3.0 V ⋅ 5 pF = 25 uA.
The typical current consumption will increase to 225uA when adding CML=5 pF.
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
Crystal Specification
Modulation is achieved by pulling of the crystal capacitance. As such to achieve
correct frequency deviation (20kHz) and frequency of operation as specified in Table
3 the crystal must meet the following specification:
Co ≤ 3 pF
ESR ≤ 50 ohm .
C L = 12 pF
Crystal parallel equivalent capacitor
Crystal equivalent series resistor
Crystal load capacitor
Output Power adjustment
A bias resistor R2 (see Figure 6) should be connected from the REXT pin to the
positive power supply VDD. The value of this resistor determines the output power
level. See table 5 for choice of R2 value.
Power setting resistor R2
22kΩ
82kΩ
180kΩ
RF output power
10dBm
0dBm
-10dBm
DC current consumption
30mA
15mA
9mA
Conditions: VDD = 3.0V, VSS = 0V, TA = 27ºC, Load impedance = 400 Ω.
Table 5. RF output power setting for the nRF902.
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
DEFINITIONS
Data sheet status
Objective product specification
Preliminary product
specification
Product specification
This datasheet contains target specifications for product development.
This datasheet contains preliminary data; supplementary data may be
published from Nordic VLSI ASA later.
This datasheet contains final product specifications. Nordic VLSI ASA
reserves the right to make changes at any time without notice in order to
improve design and supply the best possible product.
Limiting values
Stress above one or more of the limiting values may cause permanent damage to the device. These are stress
ratings only and operation of the device at these or at any other conditions above those given in the
Specifications sections of the specification is not implied. Exposure to limiting values for extended periods may
affect device reliability.
Application information
Where application information is given, it is advisory and does not form part of the specification.
Table 6. Definitions.
Nordic VLSI ASA reserves the right to make changes without further notice to the
product to improve reliability, function or design. Nordic VLSI does not assume any
liability arising out of the application or use of any product or circuits described
herein.
LIFE SUPPORT APPLICATIONS
These products are not designed for use in life support appliances, devices, or systems
where malfunction of these products can reasonably be expected to result in personal
injury. Nordic VLSI ASA customers using or selling these products for use in such
applications do so at their own risk and agree to fully indemnify Nordic VLSI ASA
for any damages resulting from such improper use or sale.
Preliminary specification: Revision Date: 06/04/2000.
Datasheet order code: 060400-nRF902.
All rights reserved ®. Reproduction in whole or in part is prohibited without the prior
written permission of the copyright holder.
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
YOUR NOTES
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PRELIMINARY PRODUCT SPECIFICATION
nRF902 Single chip 868 MHz Transmitter
Nordic VLSI ASA – World Wide Distributors
For Your nearest dealer, please see http://www.nvlsi.no
Main Office:
Vestre Rosten 81, N-7075 Tiller, Norway
Phone: +47 72 89 89 00, Fax: +47 72 89 89 89
E-mail: [email protected]
Visit the Nordic VLSI ASA website at http://www.nvlsi.no
Revision 1.0
April 2000