Features
• • • • •
Fully Integrated Low IF Receiver Fully Integrated GFSK Modulator for 72, 144, 288, 576 and 1152 Kbits/s High Sensitivity of Typically –93 dBm Due to Integrated LNA High Output Power of Typically +4 dBm Multi-channel Operation – 95 Channels – Support Frequency Hopping (ETSI) and Digital Modulation (FCC) Supply-voltage Range 2.9V to 3.6V (Unregulated) Auxiliary Voltage Regulator on Chip (3.2V to 4.6V) Low Current Consumption Few Low-cost External Components Integrated Ramp-signal Generator and Power Control for an Additional Power Amplifier Low Profile Lead-free Plastic Package QFN32 (5 mm × 5 mm × 0.9 mm) RoHs Compliant
• • • • • • •
Low-IF 2.4-GHz ISM Transceiver ATR2406
Applications
• • • • • • •
High-tech Multi-user Toys Wireless Game Controllers Telemetry Wireless Audio/Video Electronic Point of Sales Wireless Head Set FCC CFR47, Part 15, ETSI EN 300 328, EN 300 440 and ARIB STD-T-66 Compliant Radio Links
1. Description
The ATR2406 is a single chip RF transceiver intended for applications in the 2.4-GHz ISM band. The QFN32-packaged IC is a complete transceiver including image rejection mixer, low IF filter, FM demodulator, RSSI, TX preamplifier, power-ramping generator for external power amplifier, integrated synthesizer, and a fully integrated VCO and TX filter. No mechanical adjustment is necessary in production. The RF transceiver offers a clock recovery function on-chip.
4779L–ISM–09/06
Figure 1-1.
Block Diagram
REG_DEC VREG REG_CTRL VS_REG IREF VS_SYN
VREG_VCO
VCO REG
AUX REG
AUX REG
VS_IFD VS_IFA VS_RX/TX LIMITER RSSI DEMOD RX_DATA
LNA RX_IN
IR-Mixer
BP
RSSI PA TX_OUT Divider by 2 VCO BUS CLOCK DATA ENABLE TEST1 TEST2 RAMP_OUT RAMP GEN PLL GAUSSIAN FILTER PU_REG CTRL LOGIC PU_TRX RX_ON TX_ON nOLE
CP
REF_CLK TX_DATA
VTUNE
2. Pin Configuration
Figure 2-1. Pinning QFN32 - 5 × 5
ENABLE DATA CLOCK TX_DATA RX_DATA PU_TRX nOLE TX_ON PU_REG REF_CLK RSSI VS_IFD VS_IFA RX-CLOCK IC IREF
1 2 3 4 5 6 7 8
32 31 30 29 28 27 26 25 24 23 22 ATR2406 21 20 19 18 17 9 10 11 12 13 14 15 16
REG_CTRL VREG VS_REG REG_DEC VREG_VCO VTUNE CP VS_SYN
RX_ON IC IC RAMP_OUT TX_OUT RX_IN1 RX_IN2 VS_TRX
2
ATR2406
4779L–ISM–09/06
ATR2406
Table 2-1.
Pin 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 Paddle
Pin Description
Symbol PU_REG REF_CLK RSSI VS_IFD VS_IFA RX-CLOCK IC IREF REG_CTRL VREG VS_REG REG_DEC VREG_VCO VTUNE CP VS_SYN VS_TRX RX_IN2 RX_IN1 TX_OUT RAMP_OUT IC IC RX_ON TX_ON nOLE PU_TRX RX_DATA TX_DATA CLOCK DATA ENABLE GND Function Power-up input for auxiliary regulator Reference frequency input Received signal strength indicator output Digital supply voltage Analog supply voltage for IF circuits RX-CLOCK, if RX mode with clock recovery is active Internally connected. Connect to VS if internal AUX regulator is not used External resistor for band-gap reference Auxiliary voltage regulator control output Auxiliary voltage regulator output Auxiliary voltage regulator supply voltage Decoupling pin for VCO_REG VCO voltage regulator VCO tuning voltage input Charge-pump output Synchronous supply voltage Transmitter receiver supply voltage Differential receiver input 2 Differential receiver input 1 TX driver amplifier output Ramp generator output for PA power ramping Internally connected, do not connect on PCB Internally connected, do not connect on PCB RX control input TX control input Open loop enable input RX/TX/PLL/VCO power-up input RX data output TX data input 3-wire-bus: Clock input 3-wire-bus: Data input 3-wire-bus: Enable input Ground
3
4779L–ISM–09/06
3. Functional Description
3.1 Receiver
The RF signal at RF_IN is differentially fed through the LNA to the image rejection mixer IR_MIXER, driving the integrated low-IF band-pass filter. The IF frequency is 864 kHz. The limiting IF_AMP with an integrated RSSI function feeds the signal to the digital demodulator DEMOD. No tuning is required. Data slicing is handled internally.
3.2
Clock Recovery
For a 1152-kBit/s data rate, the receiver has a clock recovery function on-chip. The receiver includes a clock recovery circuit which regenerates the clock out of the received data. The advantage is that this recovered clock is synchronous to the clock of the transmitting device (and thus to the transmitted data), which significantly reduces the load of the processing microcontroller. The falling edge of the clock is the optimal sampling position for the RX_Data signal, so at this event the data must be sampled by the microcontroller. The recovered clock is available at pin 6.
3.3
Transmitter
The transmit data at TX_DATA is filtered by an integrated Gaussian filter (GF) and fed to the fully integrated VCO operating at twice the output frequency. After modulation, the signal is frequency divided by 2 and fed to the internal preamplifier PA. This preamplifier supplies typically +4 dBm output power at TX_OUT. A ramp-signal generator RAMP_GEN, providing a ramp signal at RAMP_OUT for the external power amplifier, is integrated. The slope of the ramp signal is controlled internally so that spurious requirements are fulfilled.
3.4
Synthesizer
The IR_MIXER, the PA, and the programmable counter (PC) are driven by the fully integrated VCO, using on-chip inductors and varactors. The output signal is frequency divided to supply the desired frequency to the TX_DRIVER, the 0/90 degree phase shifter for the IR_MIXER, and to be used by the PC for the phase detector (PD) (fPD = 1.728 MHz). Open loop modulation is supported.
3.5
Power Supply
An integrated band-gap–stabilized voltage regulator for use with an external low-cost PNP transistor is implemented. Multiple power-down and current saving modes are provided.
4
ATR2406
4779L–ISM–09/06
ATR2406
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 Supply voltage auxiliary regulator Supply voltage Control voltages Storage temperature Input RF level ESD protection Symbol VS VS Vcontr Tstg PRF VESD_ana VESD_dig Min. –0.3 –0.3 –0.3 –40 Max. +4.7 +3.6 VS +125 +10 TBD TBD Unit V V V °C dBm V V
Electrostatic sensitive device. Observe precautions for handling.
5. Operating Range
Parameters Supply voltage Auxiliary regulator supply voltage Temperature ambient Input frequency range Symbol VS VS_BATT Tamb fRX Min. 2.9 3.2 –10 2400 Max. 3.6 4.6 +60 2483 Unit V V °C MHz
5
4779L–ISM–09/06
6. Electrical Characteristics
VS = 3.6V with AUX regulator, Tamb = 25°C, unless otherwise specified No. 1 1.1 1.2 1.3 1.4 Parameters Supply Supply voltage Supply voltage RX supply current TX supply current Battery lifetime of a remote control application using an AVR® Supply current in power-down mode Supply current in power-down mode Voltage Regulator AUX regulator VCO regulator Transmitter Part TX data rate Output power TX data filter clock Frequency deviation Frequency deviation scaling(3) 9 taps in filter To be tuned by GFCS bits GFFM = GFFM_nom × GFCS (Refer to bus protocol D9 to D11) With standard loop filter and slot length of 1400 µs (Refer to the application note “ATR2406 Loop Filter and Data Rates”) BW = 100 kHz(1) PTX fTXFCLK GFFM_nom GFCS 60 72/144/288/576/1152 4 10.368/13.824 ±400 130 kBits/s dBm MHz kHz % VREG VREG_VCO 3.0 2.7 V V With AUX regulator Without AUX regulator CW mode (peak current) Burst mode at 10 Kbits/s(4) CW mode (peak current) Burst mode at 10 Kbits/s(4) See Section 10. ”Appendix: Current Calculations for a Remote Control” on page 20 With AUX regulator PU_TRX = 0; PU_REG = 0 Without AUX regulator PU_TRX = 0; PU_REG = 0 IS IS 6MHz Blnear
40 38 47
dBc dBc dBc
Out of band rejection 5.10 2300 MHz to 2394 MHz 2506 MHz to 2600 GHz Out of band rejection 5.11 30 MHz to 2300 MHz 2600 MHz to 6 GHz 6 6.1 6.2 7 7.1 7.2 7.3 Notes: RSSI Part Maximum RSSI output voltage
Blfar
57
dBc
Under high RX input signal level
VRSSImax VRSSI
2.1 1.9 0.1
V V V
RSSI output voltage, monotonic With –33 dBm at RF input over range –96 dBm to –36 dBm With –96 dBm at RF input VCO Oscillator frequency defined at TX output Frequency control voltage range VCO tuning input gain defined at TX output Over full temperature range(1)
2400 VVTUNE GVCO 0.5 240
2483 VCC – 0.5
MHz V MHz/V
1. Measured and guaranteed only on the Atmel® evaluation board, including microstrip filter, balun, and Smart Radio Frequency (Smart RF) firmware. Conducted measured. 2. Timing is determined by external loop filter characteristics. Faster timing can be achieved by modification of the loop filter. For further information refer to the application notes. 3. The Gaussian filter control setting (GFCS) is used to compensate production tolerances by tuning the modulation deviation in production to the nominal value of 400 kHz. 4. Burst mode with 0.9% duty cycle
7
4779L–ISM–09/06
6. Electrical Characteristics (Continued)
VS = 3.6V with AUX regulator, Tamb = 25°C, unless otherwise specified No. 8 8.1 8.2 8.3 8.4 8.5 9 9.1 10 Parameters Synthesizer External reference input frequency Sinusoidal input signal level (peak-to-peak value) Scaling factor prescaler Scaling factor main counter Scaling factor swallow counter Phase Detector Phase detector comparison frequency Charge-pump Output VCP = 1/2 VCC VCP = 1/2 VCC Reference clock stable Reference clock stable Reference clock stable Reference clock stable Reference clock stable Reference clock stable Reference clock stable Logic 1 Logic 0 Logic 1 Logic 0 Logic 1 or logic 0 ICP IL TX → RX time RX → TX time CS time PD → TR time PD → RX time PRR time PLL set time VIH VIL VOH VOL Ibias fCLKmax 0 –5 +5 10 1.4 –0.3 ±2 ±100 200 200 200 250 200 3 200 3.1 +0.4 3.1 1000 mA pA µs µs µs µs µs µs µs V V V V µA MHz fPD 1728 kHz D7 = 0 D7 = 1 AC-coupled sine wave REF_CLK REF_CLK SPSC SMC SSC 0 500 32/33 86/87/88/89 31 10.368 13.824 1000 MHz MHz mVPP Test Conditions Symbol Min. Typ. Max. Unit
10.1 Charge-pump output current 10.2 Leakage current 11 Timing Conditions(1)(2) 11.1 Transmit to receive time 11.2 Receive to transmit time 11.3 Channel switch time 11.4 Power down to transmit 11.5 Power down to receive 11.6 Programming register 11.7 PLL settling time 12 12.1 HIGH-level input voltage 12.2 LOW-level input voltage 12.3 HIGH-level output voltage 12.4 LOW-level output voltage 12.5 Input bias current 12.6 3-wire bus clock frequency Notes:
Interface Logic Input and Output Signal Levels, Pin DATA, CLOCK, ENABLE
1. Measured and guaranteed only on the Atmel® evaluation board, including microstrip filter, balun, and Smart Radio Frequency (Smart RF) firmware. Conducted measured. 2. Timing is determined by external loop filter characteristics. Faster timing can be achieved by modification of the loop filter. For further information refer to the application notes. 3. The Gaussian filter control setting (GFCS) is used to compensate production tolerances by tuning the modulation deviation in production to the nominal value of 400 kHz. 4. Burst mode with 0.9% duty cycle
8
ATR2406
4779L–ISM–09/06
ATR2406
7. PLL Principle
Figure 7-1. PLL Principle
Programable counter PC "- Main counter MC "- Swallow counter SC fVCO = 1728 kHz × (SMC × 32 + SSC)
External loop filter
Phase frequency detector PD fPD = 1728 kHz
PA driver Charge pump VCO Divider by 2 Mixer
Gaussian filter GF
Reference counter RC REF_CLK 10.368 MHz 13.824 MHz D7 0 1
PLL reference Frequency REF_CLK Baseband controller
TXDAT
9
4779L–ISM–09/06
Table 7-1 shows the LO frequencies for RX and TX in the 2.4-GHz ISM band. There are 95 channels available. Since the ATR2406 supports wideband modulation with 400-kHz deviation, every second channel can be used without overlap in the spectrum.
Table 7-1.
Mode
LO Frequencies
fIF / kHz Channel C0 C1 fANT / MHz 2401.056 2401.920 ... 2481.408 2482.272 2401.056 2401.920 ... 2481.408 2482.272 fVCO / MHz divided by 2 2401.056 2401.920 ... 2481.408 2482.272 2401.920 2402.784 ... 2482.272 2483.136 SMC 86 86 ... 89 89 86 86 ... 89 89 SSC 27 28 ... 24 25 28 29 ... 25 26 N 2779 2780 ... 2872 2873 2780 2781 ... 2873 2874
TX
... C93 C94 C0 C1
RX
864
... C93 C94
7.1
TX Register Setting
The following 16-bit word has to be programmed for TX.
MSB Data bits D15 0 D14 1 D13 PA D12 D11 D10 GFCS D9 D8 1 D7 RC D6 MC D5 D4 D3 D2 SC D1
LSB
D0
Note:
D12 and D13 are only relevant if ramping generator in conjunction with external PA is used, otherwise it can be programmed 0 or 1.
Table 7-2.
Output Power Settings with Bits D12 - D13
PA (Output Power Settings) D13 0 0 1 1 D12 0 1 0 1 RAMP_OUT (Pin 21) 1.3V 1.35V 1.4V 1.75V
The VRAMP voltage is used to control the output power of an external power amplifier. The voltage ramp is started with the TX_ON signal. These bits are only relevant in TX mode.
10
ATR2406
4779L–ISM–09/06
ATR2406
7.2 RX Register Setting
There are two RX settings possible. For a data rate of 1152 kBits/s, an internal clock recovery function is implemented.
7.3
Register Setting Without Clock Recovery
Must be used for data rates below 1.152 Mbits/s.
MSB Data bits D15 0 D14 1 D13 X D12 X D11 X D10 X D9 X D8 0 D7 RC D6 MC D5 D4 D3 D2 SC D1
LSB
D0
Note:
X values are not relevant and can be set to 0 or 1.
7.4
RX Register Setting with Internal Clock Recovery
Recommended for 1.152-Mbit/s data rate. The output pin of the recovered clock is pin 6. The falling edge of the recovered clock signal samples the data signal.
MSB Data bits D24 1 D23 0 D22 1 D21 0 D20 0 D19 0 D18 0 D17 0 D16 0
LSB Data bits D15 0 D14 0 D13 X D12 X D11 X D10 X D9 X D8 0 D7 RC D6 MC D5 D4 D3 D2 SC D1 D0
Note:
X values are not relevant and can be set to 0 or 1.
7.5
PLL Settings
RC, MC and SC bits control the synthesizer frequency as shown in Table 7-3, Table 7-4 on page 12 and Table 7-5 on page 12. Formula for calculating the frequency: TX frequency: fANT = 864 kHz × (32 × SMC + SSC) RX frequency: fANT = 864 kHz × (32 × SMC + SSC – 1) Table 7-3. PLL Settings of the Reference Counter Bit D7
RC (Reference Counter) D7 0 1 CLK Reference 10.368 MHz 13.824 MHz
11
4779L–ISM–09/06
Table 7-4.
PLL Settings of the Main Counter Bits D5 to D6
MC (Main Counter) D6 0 0 1 1 D5 0 1 0 1 SMC 86 87 88 89
Table 7-5.
PLL Settings of the Swallow Counter Bits D0 to D4
SC (Swallow Counter)
D4 0 0 0 ... 1 1 1
D3 0 0 0 ... 1 1 1
D2 0 0 0 ... 1 1 1
D1 0 0 1 ... 0 1 1
D0 0 1 0 ... 1 0 1
SSC 0 1 2 ... 29 30 31
7.6
GFCS Adjustment
The Gaussian filter control setting (GFCS) is used to compensate for production tolerances by tuning the modulation deviation in production to the nominal value of 400 kHz. These bits are only relevant in TX mode.
Table 7-6.
GFCS Adjustment of Bits D9 - D11
GFCS
D11 0 0 0 0 1 1 1 1
D10 0 0 1 1 0 0 1 1
D9 0 1 0 1 0 1 0 1
GFCS 60% 70% 80% 90% 100% 110% 120% 130%
12
ATR2406
4779L–ISM–09/06
ATR2406
7.7 Control Signals
The various transceiver functions are activated by the following control signals. A timing proposal is shown in Figure 7-3 on page 14
Table 7-7.
Control Signals and Functions
Functions Activates AUX voltage regulator and the VCO voltage regulator supplying the complete transceiver Activates RX/TX blocks Activates RX circuits: DEMOD, IF AMP, IR MIXER Activates TX circuits: PA, RAMP GEN, Starts RAMP SIGNAL at RAMP_OUT Disables open loop mode of the PLL
Signal PU_REG PU_TRX RX_ON TX_ON nOLE
7.8
Serial Programming Bus
The transceiver is programmed by the SPI (CLOCK, DATA and ENABLE). After setting the enable signal to low, the data is transferred bit by bit into the shift register on the rising edge of the clock signal, starting with the MSBit. When the enable signal has returned to high, the programmed information is active. Additional leading bits are ignored and there is no check made of how many clock pulses arrived during enable low. The programming of the transceiver is done by a 16-bit or 25-bit data word (for the RX clock recovery mode).
7.9
3-wire Bus Timing
3-wire Bus Protocol Timing Diagram
DATA CLOCK ENABLE TPER TL TS TC TH
Figure 7-2.
TEC
TT
Table 7-8.
Description Clock period
3-wire Bus Protocol Table
Symbol TPER TS TH TC TL TEC TT Minimum Value 100 20 20 60 100 0 250 Unit ns ns ns ns ns ns ns
Set time data to clock Hold time data to clock Clock pulse width Set time enable to clock Hold time enable to data Time between two protocols
13
4779L–ISM–09/06
Figure 7-3.
3W_ENA Pin 32
nOLE Pin 26 REF_CLK
> 50 µs
Signals to TRX (Input)
Signals from TRX (Output)
14
C3 Programming Active RX-slot Programming Active TX-slot Power-down C4 C1 C2 C3 C5 C1 Power-down optional Power-up optional
> 40 µs > 50 µs
C1
C2
MODE
ATR2406
Data
Pin Name
Power-down
Power-up
PU_REG Pin 1
PU_TRX Pin 27
> 40 µs
TX_DATA Pin 29
Preamble (1-0-1-0)
Example TX and RX Timing Diagram
3W_CLK Pin 30
16/25 bits > 200 µs > 200 µs 16 bits
3W_DATA Pin 31
REF_CLK Pin 2
REF_CLK
RX_ON Pin 24
TX_ON Pin 25 Data
RX_DATA Pin 28 valid signal
VS 0V VS 0V
RSSI Pin 3
RAMP_OUT Pin 21 connected to RAMP_IN of optional PA
Note:
1. Keep input signals on low level during power-down state of TRX
4779L–ISM–09/06
ATR2406
Table 7-9.
Condition C1
Description of the Conditions/States
Description Power down ATR2406 is switched off and the supply current is lower than 1 µA. Power up ATR2406 is powered up by toggling PU_REG and PU_TRX to high. PU_REG enables the external AUX regulator transistor including VCO regulator. PU_TRX enables internal blocks like the PLL and the VCO. Depending on the value of the external capacitors (for example, at the AUX regulator, if one is used), it is necessary to wait at least 40 µs until the different supply voltages have settled. Programming The internal register of the ATR2406 is programmed via the three-wire interface. At TX, this is just the PLL (transmit channel) and the deviation (Gaussian filter). At RX, this is just the PLL (receive channel) and, if the clock recovery is used, also the bits to enable this option. At the start of the three-wire programming, the enable signal is toggled from high to low to enable clocking the data into the internal register. When the enable signal rises again to high, the programmed data is latched. This is the time point at which the settling of the PLL starts. It is necessary to wait the settling time of 200 µs so that the VCO frequency is stable. The reference clock needs to be applied to ATR2406 for at least the time when the PLL is in operation, which is the programming state (C3) and the active slot (C4, C5). Out of the reference clock, several internal signals are also derived, for example, the Gaussian filter circuitry and TX_DATA sampling. This is the receive slot where the transmit burst is received and data as well as recovered clock are available. This is the active transmit slot. As soon as TX_DATA is applied to ATR2406, the signal nOLE toggles to low which enables modulation in open-loop mode. The preamble (1-0-1-0 pattern) should start being sent at the start of TX_ON.
C2
C3
C4
C5
7.10
Received Signal Strength Indication (RSSI)
The RSSI is given as an analog voltage at the RSSI pin. A typical plot of the RSSI value is shown in Figure 7-4. Figure 7-4. Typical RSSI Value versus Input Power
2.5
2.0
RSSI Level (V)
1.5
1.0
0.5
0.0 -130
-110
-90
-70
-50
-30
-10
10
RF Level (dBm)
15
4779L–ISM–09/06
8. Application Circuit
The ATR2406 requires only a few low-cost external components for operation. A typical application is shown in Figure 8-3 on page 17.
8.1
Typical Application Circuit
Figure 8-1. Microcontroller Interfacing with General Purpose MCU, Pin Connections between Microcontroller and ATR2406
Microcontroller RF-DATA Interface
ATR2406 TX_DATA RX_DATA RX-CLOCK ENABLE CLOCK DATA Ctrl_Lines REF_CLK
XTAL(1)
XTAL_OUT
Example with AVR MCU
Figure 8-2.
AVR_MCU
USART
TXD RXD XCK
Configuration and control
ATR2406
RF_DATA
TX_DATA RX_DATA
R
RX-CLOCK
GPIO
GPIO1 GPIO2 GPIO3 GPIO4 GPIO5
RF_CTRL
ENABLE CLOCK DATA nOLE TX_ON RX_ON PU_REG PU_TRX RSSI REF_CLK
13.824 MHz XTAL
Note:
1. XTAL: for example, XRFBCC-NANL; 13.824 MHz, 10 ppm Order at: Taitien Electronic, Taitien Specific No.: A009-x-B26-3, SMD
16
ATR2406
4779L–ISM–09/06
Figure 8-3.
TX_DATA
RX_DATA
PU_TRX
nOLE
TX_ON
RX_ON
RAMP_OUT
VBATT
ENABLE
DATA
CLOCK
J24
R1
NC
RX-CLOCK
RSSI
REF_CLK
PU_REG
C11
18p
32
31
30
29
28
27
26
25
IC2
C9 24 RX_ON TP1
DATA
CLOCK
ENABLE
PU_TRX
C6
C7
2p2
2p2
C3
TX_DATA
4
5 TX_OUT 19 C10 18 17 1p8 RX_IN1 RX_IN2 20
VS_IFD
VS_IFA
ATR2406
RAMP_OUT
21
6
7
RX-CLOCK
VREG_VCO
VTUNE
REG_DEC
CP
VREG
VS_REG
VS_SYN
GND
Application Circuit for ATR2406-DEV-BOARD
C24
REG_CTRL
8 VS_TRX
IC
IREF
µStrip
3 IC TP2 22
RSSI
RX_DATA
REF_CLK
IC
1p5
9
11
12
13
14
15
10
16
G
C16
4p7 R3
62k
1p8
2 23
TX_ON
PU_REG
nOLE
1
µStrip
4n7
C23
C4
C17
NC
390p
C14
100n
NC
R6
R4
C19
470n
C13 C21 C20 22n 2n2
C18
68p
1k0
100n
1k5
VS
J2
GND2
GND7 GND8 GND9 GND4 GND5 GND6 GND1 GND3
4779L–ISM–09/06
RFOUT (Ant)
Select integrated F-antenna or SMA connector by setting the 0R resistor ANT2 F-antenna ANT ANT GND GND R2
NC
C1 SMASI 5p6
J2
µStrip Lowpassfilter
J1 J11 VBATT
4µ7
VBATT TX_ON TX_DATA PU_TRX CLOCK RX_ON
J4 J5 J6 J7 J8 J9
C15
J12 J13 J14 J15 J16 J17 RSSI J10 R5
ENABLE DATA nOLE PU_REG RX-CLOCK RX_DATA
C12
BC808 µStrip-balun
REF_CLK
J3 1k5
T1
1 3 5 7 9 11 13 15 17 19 21 23 25 27
2 4 6 8 10 12 14 16 18 20 22 24 26 28
VLSI Connector
J18 J19 J20 J21
4µ7
C20, C21, COG dielectric Slug RAMP
J26
IC2P GND
ATR2406
17
9. PCB Layout Design
Figure 9-1. PCB Layout ATR2406-DEV-BOARD
18
ATR2406
4779L–ISM–09/06
ATR2406
Table 9-1.
Part C1 C3, C10 C4 C5 C6, C7 C9 C11 C12, C15 C13, C16 C14 C17 C18 C19 C20 C21 C23 C24 L6 R3 R4 R5 R6 IC2 T1 MSUB Notes:
Bill of Materials
Value 5.6 pF 1.8 pF 390 pF 4.7 pF 2.2 pF 1.5 pF 18 pF 100 nF 4.7 µF 1 nF 3.3 nF 68 pF 470 nF Part Number GJM1555C1H5R6CB01 or GRM1555C1H5R6DZ01 GJM1555C1H1R8CB01 or GRM1555C1H1R8CZ01 GRM1555C1H391JA01 GJM1555C1H4R7CB01 or GRM1555C1H4R7CZ01 GJM1555C1H2R2CB01 or GRM1555C1H2R2CZ01 GJM1555C1H1R5CB01 or GRM1555C1H1R5CZ01 GRM1555C1H180JZ01B GRM155R71C104KA88B B45196H2475M109 GRM15R71H102KB01 GRM15R71H332KB01 GRM1555C1H680JZ01B GRM18F51H474ZB01 (0402) or GRM188R61A474KA61B (0603) Vendor Murata® Murata Murata Murata Murata Murata Murata Murata Epcos® Murata Murata Murata Murata Murata Murata Murata Murata Würth® Electronic Vishay
®
Package 0402 0402 0402 0402 0402 0402 0402 0402 3216 0402 0402 0402 0402/0603 0805 0603 0402 0402 0402 0402 0402 0402 0402 MLF32 SOT-23
Comment
NC
Optional(2) NC NC
22 nF, COG GRM21B5C1H223JA01 2.2 nF, COG GRM1885C1H222JA01 4.7 nF 4.7 pF 8.2 nH 62 kΩ 1.0 kΩ 1.5 kΩ 1.5 kΩ GRM155R71H472KA01B GRM1555C1H4R7CZ01B WE-MK0402 744784082 62k, ≤ 5% 1k0, ≤ 5% 1k5, ≤ 5% 1k5, ≤ 5%
COG, important for good RF performance COG, important for good RF performance
NC, microstrip used
Vishay Vishay Vishay Atmel Vishay, Philips®, etc.
Ref_Clk level, optional(1) Ref_Clk level, optional(1)
ATR2406 ATR2406 BC808-40, any standard type can be used, but it is BC808-40 important that be “–40”! FR4
Optional(2)
FR4, e_r = 4.4 at 2.45 GHz, H = 500 µm, T = 35 µm, tand = 0.02, surface, that is, chem. tin or chem. gold
1. Not necessary if supplied RefClk level is within specification range 2. If no AUX regulator is used, then T1 and C16 can be removed and a jumper is needed from the collector to the emitter pad. Additionally, pin 7 of the ATR2406 has to be connected to pin 4 or pin 5 to use the integrated F antenna, set jumper R2 (0R resistor 0603)
Table 9-2.
Parts Count
Parts Count Bill of Materials
Required (Minimal BOM) 14 2 2 – 1 Optional (Depending on Application) 14 4 2 – 2
Capacitors 0402 Capacitors >0402 Resistors 0402 Inductors 0402 Semiconductors
19
4779L–ISM–09/06
10. Appendix: Current Calculations for a Remote Control
Assumptions:
Protocol A data packet consists of 24 bytes. 24 bytes = 240 bits (USART connection) Tpacket_length = 210 µs at 1.152 Mbits/s The system will use five predefined channels for frequency hopping spread spectrum (FHSS) which gives improved immunity against interferers Loop filter settling time will be 110 µs If not in use, the handheld device will be in power-down mode with the AVR’s watchdog timer disabled. The AVR power-down current is typically 1.25 µA. If an external voltage regulator is used, additional power-down current has to be taken into account The base station will periodically scan all the channels of the used subset. The base station will stay on one channel for 2 seconds. If the base station receives a correct packet, an acknowledge will be returned to the handheld device. The power consumption of the base station device is not power-sensitive, as this part of the application is normally mains powered
Channel Loop filter
Handheld device
Base station device
Basic Numbers:
Peak current ATR2406 in TX at 1.152 Kbits/s Peak current ATR2406 in RX at 1.152 Kbits/s Peak current ATR2406 with synthesizer running Current ATmega88 active Current ATmega88 power down (no WDT) Current ATmega88 power down (+ WDT) Loop settling time of ATR2406 Configuration of ATR2406 Time needed for exchanging a packet at 1.152 Kbits/s 42 mA 57 mA 26 mA 5 mA 1.25 µA 5 µA 110 µs 30 µs 210 µs
Amount of Current Needed to Transmit One Packet:
Q1 = (0.005A + 0.026A) × 5030 µs = 155 µAs (charge up time ATR2406 + AVR internal calculations) Q2 = (0.005A + 0.026A) × 30 µs = 0.93 µAs (charge for configuring the ATR2406) Q3 = (0.005A + 0.026A) × 110 µs = 3.41 µAs (charge for settling the loop filter) Q4 = (0.005A + 0.042A) × 210 µs = 9.87 µAs (charge for transmitting the packet) Q5 = (0.005A) × 250 µs = 1.25 µAs (charge for turn around (TX to RX, RX to TX, etc.)) Q6 = (0.005A + 0.026A) × 30 µs = 0.93 µAs (charge for configuring the ATR2406) Q7 = (0.005A + 0.026A) × 60 µs = 1.86 µAs (charge for settling the loop filter) Q8 = (0.005A + 0.057A) × 50 µs = 3.10 µAs (charge until valid data can be received) Q9 = (0.005A + 0.057A) × 210 µs = 13.02 µAs (charge for receiving the packet) Q10 = (0.005A + 0.057A) × 50 µs = 3.1 µAs (charge for latency before receiving)
20
ATR2406
4779L–ISM–09/06
ATR2406
A successful packet exchange needs the following charge Q = Q1 + Q2 + Q3 + Q4 + Q5 + Q6 + Q7 + Q8 + Q9 + Q10 = 192.47 µAs As the described system is a FHSS system with 5 different channels, the system has to do this up to five times before the packet is acknowledged by the base station. The average will be 2.5 times. In the case of an interfered environment, some more retries may be required; therefore, it is assumed the factor will be 3. The power-up time is included only once, as the cycle will be completed without powering up and down the handheld in order to be as power efficient as possible. Average current needed for a packet exchange: 155 µAs + (37.5 µAs × 3) = 267.5 µAs If the device will be used 1000 times a day → 3.1 µA
Average current in active mode:
→ System Power Down current:
Current ATmega88: Current ATR2406: Current VREG (+ ShutDown): 1.25 µA 1.0 µA 2.75 µA
Assumed average power-down current is 5 µA.
→ Overall power consumption is 8.1 µA
It is assumed the system uses a small battery with a capacity of 100 mAh. This is 100.000 µAh.
→ Battery lifetime will be around: 12345 hours = 514 days = 1.4 years.
The most important factor is to get the power-down current as low as possible! Example: Assume a system where the handheld is used just 10 times per day. → Iactive = 0.031 µA and assuming the power-down current of this device is just 4 µA.
→ I = 0.031 µA + 4 µA = 4.03 µA → Battery lifetime will be around 24807 hours = 1033 days = 2.83 years. → Power-down current is the main factor influencing the battery lifetime.
21
4779L–ISM–09/06
11. Ordering Information
Extended Type Number ATR2406-PNQG ATR2406-DEV-BOARD ATR2406-DEV-KIT2 Package QFN32 - 5x5 – – Remarks Taped and reeled, Pb-free RF module Complete evaluation kit and reference design ATR2406 + ATmega88 MOQ 4000 1 1
12. Package Information
22
ATR2406
4779L–ISM–09/06
ATR2406
13. Recommended Footprint/Landing Pattern
Figure 13-1. Recommenced Footprint/Landing Pattern
Table 13-1.
Recommended Footprint/Landing Pattern Signs
Sign A B C a b c d e Size 3.2 mm 1.2 mm 0.3 mm 1.1 mm 0.3 mm 0.2 mm 0.55 mm 0.5 mm
23
4779L–ISM–09/06
14. 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 • Table “Electrical Characteristics” on pages 6 to 8 changed • Section 10 “Appendix: Current Calculations for a Remote Control” on pages 20 to 21 changed • Table “Ordering Information” on page 22 changed • Minor corrections to grammar and style throughout document • Put datasheet in a new template • Table “Electrical Characteristics” on pages 6 to 8 changed • Section 10 “Appendix: Current Calculations for a Remote Control” on pages 20 to 21 added • Ordering Information on page 22 changed
4779L-ISM-08/06
4779K-ISM-06/06
24
ATR2406
4779L–ISM–09/06
Atmel Corporation
2325 Orchard Parkway San Jose, CA 95131, USA Tel: 1(408) 441-0311 Fax: 1(408) 487-2600
Atmel Operations
Memory
2325 Orchard Parkway San Jose, CA 95131, USA Tel: 1(408) 441-0311 Fax: 1(408) 436-4314
RF/Automotive
Theresienstrasse 2 Postfach 3535 74025 Heilbronn, Germany Tel: (49) 71-31-67-0 Fax: (49) 71-31-67-2340 1150 East Cheyenne Mtn. Blvd. Colorado Springs, CO 80906, USA Tel: 1(719) 576-3300 Fax: 1(719) 540-1759
Regional Headquarters
Europe
Atmel Sarl Route des Arsenaux 41 Case Postale 80 CH-1705 Fribourg Switzerland Tel: (41) 26-426-5555 Fax: (41) 26-426-5500
Microcontrollers
2325 Orchard Parkway San Jose, CA 95131, USA Tel: 1(408) 441-0311 Fax: 1(408) 436-4314 La Chantrerie BP 70602 44306 Nantes Cedex 3, France Tel: (33) 2-40-18-18-18 Fax: (33) 2-40-18-19-60
Biometrics/Imaging/Hi-Rel MPU/ High-Speed Converters/RF Datacom
Avenue de Rochepleine BP 123 38521 Saint-Egreve Cedex, France Tel: (33) 4-76-58-30-00 Fax: (33) 4-76-58-34-80
Asia
Room 1219 Chinachem Golden Plaza 77 Mody Road Tsimshatsui East Kowloon Hong Kong Tel: (852) 2721-9778 Fax: (852) 2722-1369
ASIC/ASSP/Smart Cards
Zone Industrielle 13106 Rousset Cedex, France Tel: (33) 4-42-53-60-00 Fax: (33) 4-42-53-60-01 1150 East Cheyenne Mtn. Blvd. Colorado Springs, CO 80906, USA Tel: 1(719) 576-3300 Fax: 1(719) 540-1759 Scottish Enterprise Technology Park Maxwell Building East Kilbride G75 0QR, Scotland Tel: (44) 1355-803-000 Fax: (44) 1355-242-743
Japan
9F, Tonetsu Shinkawa Bldg. 1-24-8 Shinkawa Chuo-ku, Tokyo 104-0033 Japan Tel: (81) 3-3523-3551 Fax: (81) 3-3523-7581
Literature Requests
www.atmel.com/literature
Disclaimer: T he information in this document is provided in connection with Atmel products. No license, express or implied, by estoppel or otherwise, to any intellectual property right is granted by this document or in connection with the sale of Atmel products. EXCEPT AS SET FORTH IN ATMEL’S TERMS AND CONDITIONS OF SALE LOCATED ON ATMEL’S WEB SITE, ATMEL ASSUMES NO LIABILITY WHATSOEVER AND DISCLAIMS ANY EXPRESS, IMPLIED OR STATUTORY WARRANTY RELATING TO ITS PRODUCTS INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR NON-INFRINGEMENT. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT, CONSEQUENTIAL, PUNITIVE, SPECIAL OR INCIDENTAL DAMAGES (INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS OF PROFITS, BUSINESS INTERRUPTION, OR LOSS OF INFORMATION) ARISING OUT OF THE USE OR INABILITY TO USE THIS DOCUMENT, EVEN IF ATMEL HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. A tmel makes no representations or warranties with respect to the accuracy or completeness of the contents of this document and reserves the right to make changes to specifications and product descriptions at any time without notice. Atmel does not make any commitment to update the information contained herein. Unless specifically provided otherwise, Atmel products are not suitable for, and shall not be used in, automotive applications. Atmel’s products are not intended, authorized, or warranted for use as components in applications intended to support or sustain life.
© 2006 Atmel Corporation . A ll rights reserved. Atmel ®, logo and combinations thereof, Everywhere You Are®, AVR® a nd others, are registered trademarks or trademarks of Atmel Corporation or its subsidiaries. Other terms and product names may be trademarks of others.
4779L–ISM–09/06