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MICRF102
Micrel
MICRF102
QwikRadioTM UHF ASK Transmitter Final Information
General Description
The MICRF102 is a single chip Transmitter IC for remote wireless applications. The device employs Micrel's latest QwikRadioTM technology. This device is a true "data-in, antenna-out" monolithic device. All antenna tuning is accomplished automatically within the IC which eliminates manual tuning, and reduces production costs. The result is a highly reliable yet extremely low cost solution for high volume wireless applications. Because the MICRF102 is a true single-chip radio transmitter, it is easy to apply, minimizing design and production costs, and improving time to market. The MICRF102 uses a novel architecture where the external loop antenna is tuned to the internal UHF synthesizer. This transmitter is designed to comply worldwide UHF unlicensed band intentional radiator regulations. The IC is compatible with virtually all ASK/OOK (Amplitude Shift Keying/On-Off Keyed) UHF receiver types from wide-band super-regenerative radios to narrow-band, high performance super-heterodyne receivers. The transmitter is designed to work with transmitter data rates from 100 to 20k bits per second. The automatic tuning in conjunction with the external resistor, insures that the transmitter output power stays constant for the life of the battery. When coupled with Micrel's family of QwikRadioTM receivers, the MICRF102 provides the lowest cost and most reliable remote actuator and RF link system available.
Features
* * * * * * * * * * Complete UHF transmitter on a monolithic chip Frequency range 300MHz to 470MHz Data rates to 20kbps Automatic antenna alignment, no manual adjustment Low external part count Low standby current <0.04A Remote Keyless Entry Systems (RKE) Remote Fan/Light Control Garage Door Opener Transmitters Remote Sensor Data Links
Applications
Ordering Information
Part Number MICRF102BM Temperature Range -0C to +85C Package 8-Pin SOIC
Typical Application
+5V
4.7F ASK DATA INPUT RP1 100k 0.1F RP2 6.8k
MICRF102 PC VDD VSS REFOSC ASK ANTP ANTM STBY LOOP ANTENNA
(PCB TRACE)
Y1 100k +5V
Figure 1
QwikRadio is a trademark of Micrel, Inc. The QwikRadio ICs were developed under a partnership agreement with AIT of Orlando, Florida Micrel, Inc. * 1849 Fortune Drive * San Jose, CA 95131 * USA * tel + 1 (408) 944-0800 * fax + 1 (408) 944-0970 * http://www.micrel.com
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MICRF102
MICRF102
Micrel
Pin Configuration
PC 1 VDD 2 VSS 3 REFOSC 4 8 ASK 7 ANTP 6 ANTM 5 STBY
MICRF102BM
Pin Description
Pin Number 1 2 3 4 Pin Name PC VDD VSS REFOSC Pin Function Power Control Input. The voltage at this pin should be set between 0.15V to 0.35V for normal operation. Positive power supply input for the IC. This pin is the ground return for the IC. A power supply bypass capacitor connected from VDD to VSS should have the shortest possible path. This is the timing reference frequency which is the transmit frequency divided by 32. Connect a crystal (mode dependent) between this pin and VSS, or drive the input with an AC coupled 0.5Vpp input clock. See Reference Oscillator Section in this data sheet Input for transmitter stand by control pin is pulled to VDD for transmit operation and VSS for stand-by mode. Negative RF power output to drive the low side of the transmit loop antenna Positive RF power output to drive the high side of the transmit loop antenna Amplitude Shift Key modulation data input pin. For CW operation, connect this pin to VDD
5 6 7 8
STBY ANTM ANTP ASK
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Absolute Maximum Ratings (Note 1)
Supply Voltage(VDD) ..................................................... +6V Voltage on I/O Pins ............................. VSS-0.3 to VDD+0.3 Storage Temperature Range .................. -65C to + 150C Lead Temperature (soldering, 10 seconds) ........... + 300C ESD Rating .............................................................. Note 3
Operating Ratings (Note 2)
Supply Voltage (VDD) .................................... 4.75V to 5.5V Maximum Supply Ripple Voltage ............................... 10mV PC Input Range .............................. 150mV < VPC < 350mV Ambient Operating Temperature (TA) ............ 0C to +85C Programmable Transmitter Frequency Range: .................................................... 300MHz to 470MHz
Electrical Characteristics
Specifications apply for 4.75V < VDD < 5.5V, VPC = 0.35V, TA = 25C, freqREFOSC = 12.1875MHz, STBY = VDD. Bold values indicate 0C TA 85C unless otherwise noted. Parameter Power Supply Standby Supply Current, IQ MARK Supply Current, ION SPACE Supply Current, IOFF Mean Operating Current VSTBY < 0.5V, VASK < 0.5V or VASK > VDD - 0.5V @315MHz, Note 4 @433MHz, Note 4 @315MHz @433MHz 33% mark/space ratio at 315MHz, Note 4 33% mark/space ratio at 433MHz, Note 4 RF Output Section and Modulation Limits: Output Power Level, POUT Transmitted Power @315MHz; Note 4, Note 5 @433MHz; Note 4, Note 5 @315MHz @433MHz Harmonics Output, Note 10 @ 315MHz @433 MHz Extinction Ratio for ASK Varactor Tuning Range Reference Oscillator Section Reference Oscillator Input Impedance Reference Oscillator Source Current Reference Oscillator Input Voltage (peak to peak) 0.2 300 6 0.5 k A VPP Note 7 2nd harm. 3rd harm. 2nd harm. 3rd harm. 40 3 tbd tbd tbd tbd -46 -45 -50 -41 52 5 7 dBm dBm V/m V/m dBc dBc dBc pF 0.04 6 8 4 6 4.7 6.7 10.5 12 6 8.5 A mA mA mA mA mA mA Condition Min Typ Max Units
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MICRF102
MICRF102
Parameter Digital / Control Section Calibration Time Power Amplifier Output Hold Off Time from STBY Transmitter Stabilization Time from STBY Maximum Data Rate - ASK modulation VSTBY ASK pin Enable voltage ISTBY = VDD VIH, input high voltage VIL, input low voltage ASK input current
Note 1. Note 2. Note 3. Note 4.
Micrel
Condition Min Typ Max Unit
Note 8, ASK=HIGH Note 9, STDBY transition from LOW to HIGH Crystal, ESR < 20 From External Reference (500mVpp) Crystal, ESR < 20 Duty cycle of the modulating signal = 50% 20
25 6 10 19
ms ms ms ms kbits/s V 6.5 A V V A
0.75VDD 0.6VDD 5 0.75VDD 0.6VDD 0.3VDD 0.25VDD -10 0.1 10
STBY Sink Current
ASK = 0V, 5.0V input current
Exceeding the absolute maximum rating may damage the device. The device is not guaranteed to function outside its operating rating. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5k in series with 100pF. Supply current and output power are a function of the voltage input on the PC (power control) pin. All specifications in the Electrical Characteristics table applies for condition VPC = 350mV. Increasing the voltage on the PC pin will increase transmit power and also increase MARK supply current. Refer to the graphs "Output Power Versus PC Pin Voltage" and "Mark Current Versus PC Pin Voltage." Output power specified into a 50 equivalent load using the test circuit in Figure 5. Transmitted power measured 3 meters from the antenna using transmitter board TX102-2A in Figure 6. The Varactor capacitance tuning range indicates the allowable external antenna component variation to maintain tune over normal production tolerances of external components. Guaranteed by design not tested in production. When the device is first powered up or it loses power momentarily, it goes into the calibration mode to tune up the transmit antenna. After the release of the STDBY, the device requires an initialization time to settle the REFOSC and the internal PLL. The first MARK state (ASK HIGH) after exit from STDBY needs to be longer than the initialization time. The subsequent low to high transitions will be treated as data modulation whereby the envelope transition time will apply.
Note 5. Note 6. Note 7. Note 8. Note 9.
Note 10. The MICRF102 was tested to be Compliant to Part 15.231 for maximum allowable TX power, when operated in accordance with a loop antenna described in Figure 6.
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Typical Characteristics
Output Power vs PC Pin Voltage
5 OUTPUT POWER (dBm) 0
CURRENT (mA)
Mark Current vs PC Pin Voltage
25 20 15 10 5 0 0
-5 -10 -15 -20 -25 -30 -35 0 100 200 300 400 500 600 VPC (mV)
100 200 300 400 500 600 VPC (mV)
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MICRF102
MICRF102
Micrel
Functional Diagram
STBY VDD
Reference Bias
(10)
ASK
VDD
TX Bias Control
(9)
Power Amp
(8)
ANTP ANTM
PC
Prescaler Divide by 32
(5)
Buffer
(6a)
Phase Detector
VCO (4) (2) (3)
Buffer
(6b)
Antenna Tuning Control
(7)
Varactor Device REF.OSC
Reference Oscillator (1) (11)
VSS
Figure 2. MICRF102 Block Diagram
Functional Description
The block diagram illustrates the basic structure of the MICRF102. Identified in the figure are the principal functional blocks of the IC, namely the (1, 2, 3, 4, 5) UHF Synthesizer, (6a/b) Buffer, (7) Antenna tuner, (8) Power amplifier, (9) TX bias control, (10) Reference bias and (11) Process tuner. The UHF synthesizer generates the carrier frequency with quadrature outputs. The in-phase signal (I) is used to drive the PA and the quadrature signal (Q) is used to compare the antenna signal phase for antenna tuning purpose. The Antenna tuner block senses the phase of the transmit signal at the antenna port and controls the varactor capacitor to tune the antenna. The Power control unit senses the antenna signal and controls the PA bias current to regulate the antenna signal to the transmit power. The Process tune circuit generates process independent bias currents for different blocks. A PCB antenna loop coupled with a resonator and a resistor divider network are all the components required to construct a complete UHF transmitter for remote actuation applications such as automotive keyless entry. Included within the IC is a differential varactor that serves as the tuning element to insure that the transmit frequency and antenna are aligned with the receiver over all supply and temperature variations.
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difficult to match the parallel and series capacitors. Another point to take into consideration is the total ac rms current going through the internal varactor in the MICRF102. This current should not exceed 16mA rms. The parallel capacitor will absorb part of this current if the antenna dimensions are appropriate and not exaggerated larger than the one shown here. Note 3. A strong indication that the right capacitor values have been selected is the mean current with a 1kHz signal in the ASK pin. Refer to the Electrical Characteristics for the current values. Note 4. For much smaller antennas, place a blocking capacitor for the series capacitance (around 100pF to 220pF) and use the following formula for the parallel capacitance CT = CP + CVAR. The blocking capacitor is needed to ensure that no dc current flows from one antenna pin to the other. 5.) Set PC pin to the desired transmit power. Reference Oscillator Selection An external reference oscillator is required to set the transmit frequency. The transmit frequency will be 32 times the reference oscillator frequency.
fTX = 32 x fREFOSC
Applications Information
Design Process The MICRF102 transmitter design process is as follows: 1). Set the transmit frequency by providing the correct reference oscillator frequency 2). Ensure antenna resonance at the transmit frequency by: LANT = 0.2 x Length x ln(Length/d - 1.6) x 10-9 x k Where: Length is the total antenna length in mm. d is the trace width in mm. k is a frequency correction factor. LANT is the approximate antenna inductance in henries. Note 1. The total inductance however will be a little greater than the LANT calculated due to parasitics. A 2nH should be added to the calculated value. The LANT formula is an approximated way to calculate the inductance of the antenna. The inductance value will vary however, depending on pcb material, thickness, ground plane, etc. The most precise way to measure is to use a RF network analyzer. 3). Calculate the total capacitance using the following equation.
CT =
(4 x
1
2
x f 2 x L ANT
)
Where: CT total capacitance in farads. = 3.1416. f = carrier frequency in hertz. LANT inductance of the antenna in henries. 4). Calculate the parallel and series capacitors, which will resonate the antenna. 4.1). Ideally for the MICRF102 the series and parallel capacitors should have the same value or as close as possible. 4.2). Start with a parallel capacitor value and plug in the following equation. CS = 1 1 1 C - (C T VAR + CP )
Where: CVAR is the center varactor capacitance (5pF for the MICRF102) in farads. CP is the parallel capacitor in farads. CS is the series capacitor in farads. Repeat this calculation until CS and CP are very close and they can be found as regular 5% commercial values. Note 2. Ideally, the antenna size should not be larger than the one shown here. The bigger the antenna area, the higher the loaded Q in the antenna circuit will be. This will make more September 2002 7
Crystals or a signal generator can be used. Correct reference oscillator selection is critical to ensure operation. Crystals must be selected with an ESR of 20 Ohms or less. If a signal generator is used, the input amplitude must be greater than 200 mVP-P and less than 500 mVP-P. Antenna Considerations The MICRF102 is designed specifically to drive a loop antenna. It has a differential output designed to drive an inductive load. The output stage of the MICRF102 includes a varactor that is automatically tuned to the inductance of the antenna to ensure resonance at the transmit frequency. A high-Q loop antenna should be accurately designed to set the center frequency of the resonant circuit at the desired transmit frequency. Any deviation from the desired frequency will reduce the transmitted power. The loop itself is an inductive element. The inductance of a typical PCB-trace antenna is determined by the size of the loop, the width of the antenna traces, PCB thickness and location of the ground plane. The tolerance of the inductance is set by the manufacturing tolerances and will vary depending how the PCB is manufactured. The MICRF102 features automatic tuning. The MICRF102 automatically tunes itself to the antenna, eradicating the need for manual tuning in production. It also dynamically adapts to changes in impedance in operation and compensates for the hand-effect. Automatic Antenna Tuning The output stage of the MICRF102 consists of a variable capacitor (varactor) with a nominal value of 5.0pF tunable over a range from 3pF to 7pF. The MICRF102 monitors the phase of the signal on the output of the power amplifier and automatically tunes the resonant circuit by setting the varactor value at the correct capacitance to achieve resonance.
MICRF102
MICRF102
In the simplest implementation, the inductance of the loop antenna should be chosen such that the nominal value is resonant at 5pF, the nominal mid-range value of the MICRF102 output stage varactor. Using the equation:
L= 1 4 2 f 2C
Micrel
Transmit Power The transmit power specified in this datasheet is normalized to a 50Ohm load. The antenna efficiency will determine the actual radiated power. Good antenna design will yield transmit power in the range of 67dBV/m to 80dBV/m at 3 meters. The PC pin on the MICRF102 is used to set the transmit power. The differential voltage on the output of the PA (power amplifier) is proportional to the voltage at the PC pin. With more than 0.35V on the PC pin the output amplifier becomes current limited. At this point, further increase in the PC pin voltage will not increase the RF output power in the antenna pins. Low power consumption is achieved by decreasing the voltage in the PC pin, also reducing the RF output power and maximum range. Output Blanking When the device is first powered up or after a momentary loss of power the output is automatically blanked (disabled). This feature ensures RF transmission only occurs under controlled conditions when the synthesizer is fully operational, preventing unintentional transmission at an undesired frequency. Output blanking is key to guaranteeing compliance with UHF regulations by ensuring transmission only occurs in the intended frequency band.
If the inductance of the antenna cannot be set at the nominal value determined by the above equation, a capacitor can be added in parallel or series with the antenna. In this case, the varactor internal to the MICRF102 acts to trim the total capacitance value.
CS
CVARACTOR
CP
LANTENNA
Figure 4. Supply Bypassing Correct supply bypassing is essential. A 4.7uF capacitor in parallel with a 100pF capacitor is recommended. The MICRF102 is susceptible to supply-line ripple, if supply regulation is poor or bypassing is inadequate, spurs will be evident in the transmit spectrum.
+5V Transformer Output to 50 Impedance Transformation Network To 50 Termination of Spectrum Analyzer Z3
ASK DATA INPUT RP1 (100k)
MICRF102 PC ASK ANTP ANTM STBY
ON OFF L
Z2 Z1
RP2 (6.8k)
VDD VSS REFOSC
Crystal
Figure 5. Application Test Circuit For Specification Verification
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Supply Bypassing Supply bypassing consists of three capacitors; C3 = 4.7uF, C4 = 0.1uFand C5 = 100pF
+5VTX
1
Design Examples
Complete reference designs including gerber files can be downloaded from Micrel's website at www.micrel.com/product-info/qwikradio.shtml. Antenna Characteristics In this design, the desired loop inductance value is determined according to the table below. Freq. R XL Ind Q (MHz) (ohms) (ohms) (nH) (XL/R) 300 1.7 84.5 44.8 39.72 315 2.34 89.3 45.1 39.65 390 3.2 161 47.4 52.00 434 2.1 136 50.0 78.33 The reference design shown in Figure 6. has an meeting this requirement. K 0.83 0.85 0.90 0.96 antenna
PC
ASK
8
2
VDD
ANTP
7
MICRF102BM C4 0.1 F 16V C5 100pF 50V C3 4.7 F 16V
3
VSS
ANTM
6
4
REFOSC
SB
5
Figure 8. Example to Calculate CS and CP Antenna Inductance Calculation Length_mils = 2815 dmils = 70 k = 0.85 Length =
(Length_mils x 25.4)
1000
d=
(dmils x 25.4)
Length = 71.501 Figure 6 Loop antennas are often considered highly directional. In fact small loop antennas can achieve transmit patterns close in performance to a Dipole antenna. The radiation pattern below is the theoretical radiation pattern for the antenna shown in Figure 6.
E-total, phi = 0 E-total, phi = 90 0.0 30.0 30.0
1000 d = 1.778
Length L = 0.2 x Length x ln - 1.6 x 10 -9 x k d L = 44 x 10 -9 Where Length and d are in mm and L is in H; Where k is a constant dependent on pcb material, copper thickness, etc MICRF102 Series Capacitor Calculation f = 315 x 106 L = 46 x 10-9 CVAR = 5 x 10-12 CP = 12 x 10-12
60.0
60.0
(180-phi) direction
phi direction
CT =
120.0 120.0
l 4 x x f2 x L
2
C T = 5.55 x 10 -12
CSERIES = 1 1 1 - C T C VAR
150.0 180.0
150.0
Figure 7. Polar Elevation pattern at 315MHz The 0 degree plot is the radiation pattern in the plane of the transmitter PCB, the 90 degree plot represents the plane perpendicular to the PCB. Micrel's evaluation of the performance of the board in Figure 6. indicates an even more uniform radiation pattern that the theoretical plot shown here.
CSERIES = 8.2 x 10 -12
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MICRF102
MICRF102
MICRF102 Series Capacitor Calculation f = 433.92 x 106 L = 52 x 10-9 CVAR = 5 x 10-12 CP = 2.7 x 10-12
CT = 1 4 x 2 x f2 x L
Micrel
C T = 2.587 x 10 -12
CSERIES =
1 1 1 - C T C VAR + CP
CSERIES = 3.9 x 10 -12 L1 = 52 x 10-9 f1 = 433.92 106
C T1 =
1 4 x 2 x f 2 x L1
C T1 = 2.587 x 10 -12
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Package Information
0.026 (0.65) MAX) PIN 1
0.154 (3.90)
DIMENSIONS: INCHES (MM)
0.050 (1.27) 0.016 (0.40) TYP TYP
0.193 (4.90) 45 3-6
0.063 (1.60) MAX
0.057 (1.45) 0.049 (1.25) 0.197 (5.0) 0.189 (4.8) SEATING PLANE 0.244 (6.20) 0.228 (5.80)
8-Pin SOP (M)
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MICRF102
MICRF102
Micrel
MICREL, INC. 1849 FORTUNE DRIVE SAN JOSE, CA 95131
TEL
USA
+ 1 (408) 944-0800
FAX
+ 1 (408) 944-0970
WEB
http://www.micrel.com
This information is believed to be accurate and reliable, however no responsibility is assumed by Micrel for its use nor for any infringement of patents or other rights of third parties resulting from its use. No license is granted by implication or otherwise under any patent or patent right of Micrel, Inc. (c) 2002 Micrel, Incorporated
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