LT5506 40MHz to 500MHz Quadrature Demodulator with VGA DESCRIPTIO U FEATURES Wide Range 1.8V to 5.25V Supply Frequency Range: 40MHz to 500MHz -4dB to 59dB Variable Power Gain THD < 0.12% (-58dBc) at 800mVP-P Differential Output Level 8.8MHz I/Q Lowpass Output Noise Filters IF Overload Detector Baseband I/Q Amplitude Imbalance: 0.2dB Baseband I/Q Phase Imbalance: 0.6 6.8dB Noise Figure at Max Gain Input IP3 at Low Gain: - 0.5dBm Low Supply Current: 27mA Low Delay Shift Over Gain Control Range: 2ps/dB Outputs Biased Up While in Standby 16-Lead QFN 4mm x 4mm Package with Exposed Pad U APPLICATIO S IEEE802.11 High Speed Wireless LAN Wireless Local Loop The LT(R)5506 is a 40MHz to 500MHz monolithic integrated quadrature demodulator with variable gain amplifier (VGA), designed for low voltage operation. It supports standards that use a linear modulation format. The chip consists of a VGA, quadrature down-converting mixers and lowpass noise filters. The LO port consists of a divide-by-two stage and LO buffers. The IC provides all building blocks for IF down-conversion to I and Q baseband signals with a single supply voltage of 1.8V to 5.25V. The VGA gain has a linearin-dB relationship to the control input voltage. Hard-clipping amplifiers at the mixer outputs reduce the recovery time from a signal overload condition. The lowpass filters reduce the out-of-band noise and spurious frequency components. The cut-off frequency of the noise filters is approximately 8.8MHz. The external 2xLO frequency is required to be twice the IF input frequency for the mixers. The standby mode provides reduced supply current and fast transient response into the normal operating mode when the I/Q outputs are AC-coupled to a baseband chip. , LTC and LT are registered trademarks of Linear Technology Corporation. U TYPICAL APPLICATIO Total Harmonic Distortion vs IF Input Level at 1.8V Supply 280MHz IF INPUT C2 1F IF + L1 15nH C3 10pF L2 15nH C1 1nF -35 VCC THD (dBc) IF DET VCTRL L3 39nH QOUT+ /2 QOUT- 2xLO - EN STBY GND LT5506 5506 TA01 ENABLE STANDBY fIF, 1 = 280MHz fIF, 2 = 280.1MHz f2xLO = 570MHz 800mVP-P DIFFERENTIAL OUT -40 IOUT- 2xLO + C5 3.3pF IOUT+ IF - GAIN CONTROL 2xLO C4 560MHz 3.3pF INPUT -30 1.8V C3 1.8pF -45 -50 -55 -60 -60 -40 -30 -20 -50 IF INPUT POWER EACH TONE (dBm) -10 5506 TA01b 5506fa 1 LT5506 U W W W ABSOLUTE AXI U RATI GS U W U PACKAGE/ORDER I FOR ATIO (Note 1) ORDER PART NUMBER QOUT- QOUT+ IOUT+ IOUT- TOP VIEW Supply Voltage ....................................................... 5.5V Differential Voltage Between 2xLO+ and 2xLO- .......... 4V IF+, IF- ............................................. -500mV to 500mV IOUT+, IOUT-, QOUT+, QOUT- .................. VCC - 1.8V to VCC Operating Ambient Temperature (Note 2) ...................................................-40C to 85C Storage Temperature Range ..................-65C to 125C Voltage on Any Pin Not to Exceed ........................ -500mV to VCC + 500mV 16 15 14 13 GND 1 LT5506EUF 12 STBY IF+ 2 11 2xLO+ 17 IF - 3 10 2xLO- GND 4 6 7 8 VCC VCTRL IF DET VCC 9 5 EN UF PACKAGE 16-LEAD (4mm x 4mm) PLASTIC QFN TJMAX = 125C, JA = 37C/W EXPOSED PAD (PIN 17) IS GROUND MUST BE SOLDERED TO PCB Consult LTC Marketing for parts specified with wider operating temperature ranges. ELECTRICAL CHARACTERISTICS VCC = 3V. f2xLO = 570MHz, P2xLO = -5dBm (Note 5), f IF = 284MHz, PIF = -30dBm, I and Q outputs 800mVP-P into 4k differential load, TA = 25C, EN = VCC, STBY = VCC, unless otherwise noted. (Note 3) SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS IF Input fIF Frequency Range 40 to 500 MHz dBm Nominal Input Level RSOURCE = 200 Differential -79 to -22 Input Impedance IF+, IF- to GND, EN = V 100//1.2pF 1pF CC IF+, IF- to GND, EN = GND NF Noise Figure at Max Gain VCTRL = 1.7V 6.8 GL Min Gain (Note 4) VCTRL = 0.2V GH Max Gain (Note 4) VCTRL = 1.7V IIP3 Input IP3, Min Gain PIF = -22.5dBm (Note 7) -0.5 Input IP3, Max Gain PIF = -75dBm (Note 7) -49 dBm IIP2 Input IP2, Max Gain VCTRL = 1.7V -8 dBm 0.9 50 dB 8 59 dB dB dBm Demodulator I/Q Output Nominal Voltage Swing (Note 6) 0.8 VP-P Clipping Level (Note 6) 1.25 VP-P DC Common Mode Voltage VCC - 1.19 V I/Q Amplitude Imbalance (Note 8) 0.2 0.5 dB I/Q Phase Imbalance (Note 8) 0.6 3 Deg DC Offset (Notes 6, 8) 28 mV Output Driving Capability Single Ended, CLOAD 10pF 1.5 k 0.3 s STBY to Turn-On Delay I/Q Output 1dB Compression I/Q Output IM3 PIF, 1 = -25.5dBm, 280MHz PIF, 2 = -25.5dBm, 280.1MHz (Note 7) 2 -11.5 dBm - 50 dBc 5506fa 2 LT5506 ELECTRICAL CHARACTERISTICS VCC = 3V. f2xLO = 570MHz, P2xLO = -5dBm (Note 5), f IF = 284MHz, PIF = -30dBm, I and Q outputs 800mVP-P into 4k differential load, TA = 25C, EN = VCC, STBY = VCC, unless otherwise noted. (Note 3) SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS Variable Gain Amplifier (VGA) VCTRL = 0V to 1.4V 0.5 dB Temperature Gain Shift T = -40C to 85C, VCTRL = 0V to 1.4V 0.3 dB Gain Control Response Time Settled within 10% of Final Value 100 ns 0 to 1.7 V Gain Slope Linearity Error Gain Control Voltage Range Gain Control Slope 43 dB/V Gain Control Input Impedance To Internal 0.2V 25 k Delay Shift Over Gain Control Measured Over 10dB Step 2 ps/dB Baseband Lowpass Filter -3dB Cutoff Frequency 7.2 Group Delay Ripple 8.8 10.4 5 MHz ns 2xLO Input f2xLO Frequency Range P2xLO Input Power 1:2 Transformer with 240 Shunt Resistor (Note 5) Input Power LC Balun (Note 5) Input Impedance Differential Between 2xLO+ and 2xLO- -20 80 to 1000 MHz -5 dBm -10 dBm 800//0.4pF DC Common Mode Voltage VCC - 0.4 V IF Detector IF Detector Range Referred to IF Input -30 to 8 dBm Output Voltage Range For PIF = -30dBm to 8dBm 0.3 to 1.2 V Detector Response Time With External 1.8pF Load, Settling within 10% of Final Value 100 ns Power Supply VCC Supply Voltage ICC Supply Current EN = High, STBY = Low or High 1.8 26.5 5.25 36 mA V IOFF Shutdown Current EN, STBY < 350mV 0.2 30 A ISTBY Standby Current EN = Low; STBY = High 3.6 5.5 mA Enable Enable Pin Voltage EN = High Disable Enable Pin Voltage EN = Low Standby Standby Pin Voltage STBY = High No Standby Standby Pin Voltage STBY = Low Mode Note 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired. Note 2: Specifications over the -40C to 85C temperature range are assured by design, characterization and correlation with statistical process controls. Note 3: Tests are performed as shown in the configuration of Figure 6. The IF input transformer loss is substracted from the measured values. Note 4: Power gain is defined here as the I (or Q) output power into a 4k differential load, divided by the IF input power in dB. To calculate the voltage gain between the differential I output (or Q output) and the IF input, including ideal matching network, 10 * log(4k/50) = 19dB has to be added to this power gain. 1 V 0.5 1 V V 0.5 V Note 5: If a narrow-band match is used in the 2xLO path instead of a 1:2 transformer with 240 shunt resistor, 2xLO input power can be reduced to -10dBm, without degrading the phase imbalance. See Figure 11 and Figure 6. Note 6: Differential between IOUT+ and IOUT- (or differential between QOUT+ and QOUT-). Note 7: The gain control voltage VCTRL is set in such a way that the differential output voltage between IOUT+ and IOUT- (or differential between QOUT+ and QOUT-) is 800mVP-P, with the given input power PIF. Note 8: The typical parameter is defined as the mean of the absolute values of the data distribution. 5506fa 3 LT5506 U W TYPICAL PERFOR A CE CHARACTERISTICS VCC = 3V. f2xLO = 570MHz, P2xLO = -5dBm (Note 5), f IF = 284MHz, PIF = -30dBm, I and Q outputs 800mVP-P into 4k differential load, TA = 25C, EN = VCC, STBY = VCC, unless otherwise noted. (Note 3) Gain and Noise Figure Supply Current vs Supply Voltage vs Control Voltage at 3V Supply 32 60 85C 50 40 28 25C G, NF (dB) SUPPLY CURRENT (mA) 30 26 30 20 -40C 24 NF 10 GAIN 22 0 20 1.75 2.25 2.75 3.25 3.75 4.25 4.75 5.25 SUPPLY VOLTAGE (V) fIF = 284MHz f2xLO = 570MHz -10 0 0.6 0.3 0.9 1.2 1.8 1.5 VCTRL (V) 5506 G01 5506 G02 Gain and Noise Figure vs Control Voltage at 1.8V Supply Gain Flatness vs Control Voltage at 1.8V Supply 60 40 30 20 NF 10 GAIN 0 fIF = 284MHz f2xLO = 570MHz -10 0 0.3 0.6 0.9 1.2 1.5 GAIN AT -40C NF AT -40C GAIN AT 25C NF AT 25C GAIN AT 85C NF AT 85C GAIN DEVIATIN FROM LINEAR FIT (dB) 0.5 50 G, NF (dB) GAIN AT 25C NF AT 25C GAIN AT -40C NF AT -40C GAIN AT 85C NF AT 85C 0.4 0.3 0.2 25C 0.1 85C 0 -0.1 -40C -0.2 -0.3 -0.4 -0.5 1.8 0 VCTRL (V) 0.3 0.9 0.6 VCTRL (V) 1.2 5506 G03 1.5 5506 G04 Gain and Noise Figure vs IF Frequency Gain and Noise Figure vs Control Voltage and VCC 60 60 50 50 40 40 GAIN, VCTRL = 1.6V G, NF (dB) G, NF (dB) NF, VCTRL = 0.2V 30 20 NF 10 GAIN 0 fIF = 284MHz f2xLO = 570MHz -10 0 0.3 0.6 0.9 1.2 1.5 1.8 VCTRL (V) 5506 G05 GAIN AT 1.8V NF AT 1.8V GAIN AT 3V NF AT 3V GAIN AT 5.25V NF AT 5.25V GAIN, VCTRL = 0.9V 30 NF, VCTRL = 0.9V 20 NF, VCTRL = 1.6V 10 0 GAIN, VCTRL = 0.2V -10 10 100 IF FREQUENCY (MHz) 1000 5506 G06 5506fa 4 LT5506 U W TYPICAL PERFOR A CE CHARACTERISTICS VCC = 3V. f2xLO = 570MHz, P2xLO = -5dBm (Note 5), f IF = 284MHz, PIF = -30dBm, I and Q outputs 800mVP-P into 4k differential load, TA = 25C, EN = VCC, STBY = VCC, unless otherwise noted. (Note 3) Total Harmonic Distortion vs IF Input Power at 3V Supply and 800mVP-P Differential Out -30 fIF,1 = 280MHz fIF,2 = 280.1MHz f2xLO = 570MHz -35 -45 THD (dBc) -40C -50 -35 -35 -40 -40 -45 -50 -55 -50 -60 -60 -40 -20 -30 IF INPUT POWER EACH TONE (dBm) 5506 G07 85C -55 -40 -30 800mVP-P DIFFERENTIAL OUT fIF,1 = 280MHz fIF,2 = 280.1MHz f2xLO = 570MHz -35 -50 -45 -60 -60 -40 -20 -30 IF INPUT POWER EACH TONE (dBm) Total Harmonic Distortion vs IF Input Power at 500mVP-P Differential Out Total Harmonic Distortion vs IF Input Power and Supply Voltage 5506 G08 THD (dBc) 3V -45 1.8V VCC = 3V -5 -55 -40C 5.25V 25C -65 -55 -60 -60 -50 -70 -45 -40 -20 -30 IF INPUT POWER EACH TONE (dBm) LPF Frequency Response vs Baseband Frequency and Supply Voltage 85C -25 -20 1.4 fIF = 280MHz -20 -40C 25C 85C 0.6 25 5505 G13 0.2 -40 1.0 0.8 -40C 25C 85C 0.6 0.4 0.4 10 15 20 5 BASEBAND FREQUENCY (MHz) fIF = 280MHz 1.2 1.0 0.8 25 IF Detector Output Voltage vs IF Input CW Power at 1.8V Supply IF DET OUTPUT (V) IF DET OUTPUT (V) -15 10 15 20 5 BASEBAND FREQUENCY (MHz) 0 5505 G12 1.2 0 -15 5506 G11 1.4 -10 -10 IF Detector Output Voltage vs IF Input CW Power at 3V Supply 3V 1.8V 5.25V 25C 85C -40C -20 -40 -35 -30 -25 IF INPUT POWER EACH TONE (dBm) 5506 G10 0 -5 5506 G09 0 -60 -50 -50 -40 -20 -30 IF INPUT POWER EACH TONE (dBm) LPF Frequency Response vs Baseband Frequency and Temperature fIF,1 = 280MHz fIF,2 = 280.1MHz f2xLO = 570MHz -50 -40 MAGNITUDE (dB) -40C 85C -65 -60 -25 -45 25C fIF = 40MHz -55 fIF,1 = 280MHz fIF,2 = 280.1MHz f2xLO = 570MHz -50 fIF = 550MHz 25C -60 THD (dBc) fIF = 280MHz MAGNITUDE (dB) THD (dBc) -40 -30 800mVP-P DIFFERENTIAL OUT 3V SUPPLY THD (dBc) -30 Total Harmonic Distortion vs IF Input Power at 1.8V Supply and 800mVP-P Differential Out Total Harmonic Distortion vs IF Input Power and IF Frequency -30 -20 -10 0 IF INPUT CW POWER (dBm) 10 5506 G14 0.2 -40 -30 -20 -10 0 IF INPUT CW POWER (dBm) 10 5506 G15 5506fa 5 LT5506 U W TYPICAL PERFOR A CE CHARACTERISTICS VCC = 3V. f2xLO = 570MHz, P2xLO = -5dBm (Note 5), f IF = 284MHz, PIF = -30dBm, I and Q outputs 800mVP-P into 4k differential load, TA = 25C, EN = VCC, STBY = VCC, unless otherwise noted. (Note 3) IF Detector Output Voltage vs IF Input CW Power and Supply Voltage 1.6 fIF = 280MHz 3V 5.25V IF DET OUTPUT (V) IF DET OUTPUT (V) 95 VCC = 3V 1.0 1.8V 0.8 0.6 0.4 -30 -20 -10 0 IF INPUT CW POWER (dBm) 10 fIF = 280MHz 1.2 93 fIF = 550MHz 1.0 fIF = 40MHz 0.8 92 91 0.6 90 0.4 89 0.2 -40 fIF = 284MHz, 25C fIF = 284MHz, -40C fIF = 284MHz, 85C fIF = 40MHz, 25C fIF = 550MHz, 25C 94 1.4 1.2 0.2 -40 Phase Relation Between I and Q Outputs vs LO Input Power PHASE (DEG) 1.4 IF Detector Output Voltage vs IF Input CW Power and IF Frequency -30 -20 -10 0 IF INPUT CW POWER (dBm) 5506 G16 10 5506 G17 88 -20 -15 0 -5 -10 LO INPUT POWER (dBm) 5 10 5506 G18 U U U PI FU CTIO S GND (Pins 1, 4, 17): Ground. Pins 1 and 4 are connected to each other internally. The Exposed Pad (Pin 17) is not connected internally to Pins 1 and 4. For chip functionality, the Exposed Pad and either Pin 1 or Pin 4 must be connected to ground. For best RF performance, Pin 1, Pin 4 and the Exposed Pad should be connected to RF ground. IF+, IF- (Pins 2, 3): Differential Inputs for the IF Signal. Each pin must be DC grounded through an external inductor or RF transformer with central ground tap. This path should have a DC resistance lower than 2 to ground. EN (Pin 9): Enable Input. When the enable pin voltage is higher than 1V, the IC is completely turned on. When the input voltage is less than 0.5V, the IC is turned off, except the part of the circuit associated with standby mode. 2xLO-, 2xLO+ (Pins 10, 11): Differential Inputs for the 2xLO Input. The 2xLO input frequency must be twice that of the IF frequency. The internal bias voltage is VCC - 0.4V. STBY (Pin 12): Standby Input. When the STBY pin is higher than 1V, the standby mode circuit is turned on to prebias the I/Q buffers. When the STBY pin is less than 0.5V, the standby mode circuit is turned off. VCC (Pins 5 and 8): Power Supply. These pins should be decoupled to ground using 1000pF and 0.1F capacitors. QOUT-, QOUT+ (Pins 13, 14): Differential Baseband Outputs of the Q Channel. Internally biased at VCC - 1.19V. VCTRL (Pin 6): VGA Gain Control Input. This pin controls the IF gain and its typical input voltage range is 0.2V to 1.7V. It is internally biased via a 25k resistor to 0.2V, setting a low gain if the VCTRL pin is left floating. IOUT-, IOUT+ (Pins 15, 16): Differential Baseband Outputs of the I Channel. Internally biased at VCC - 1.19V. IF DET (Pin 7): IF Detector Output. For strong IF input signals, the DC level at this pin is a function of the IF input signal level. 5506fa 6 LT5506 W BLOCK DIAGRA IF + 2 I-MIXER CLIPPER LPF VGA IF - 3 16 IOUT+ 15 IOUT- 90 7 IF DET VCTRL 2xLO + 6 Q-MIXER 11 /2 2xLO - 10 9 0 LPF - 13 QOUT CLIPPER 12 STBY EN + 14 QOUT 5506 BD U W U U APPLICATIO S I FOR ATIO The LT5506 consists of variable gain amplifier (VGA), I/Q demodulator, quadrature LO generator, hard clipping amplifiers (clippers), lowpass filters (LPFs) and bias circuitry. The IF signal is fed to the inputs of the VGA. The VGA gain is typically set by an external signal in such a way that the amplified IF signal delivered to the I/Q mixers is constant. The IF signal is then converted into I/Q baseband signals using the I/Q down-converting mixers. The quadrature LO signals that drive the mixers are internally generated from the on-chip divide-by-two circuit. The I/Q signals are passed through a pair of hard-clipping amplifiers (clippers), which protect the subsequent lowpass filters from overloading. After externally setting the required gain, these amplifiers should not clip. However, in the event of overload, they reduce the settling time of the (optional) external AC coupling capacitors by preventing asymmetrical charging and discharging effects. The second order baseband lowpass filters remove the out-of-band noise and harmonic content generated by the mixers and the clippers. The I/Q baseband outputs are buffered by output drivers. VGA and Input Matching The VGA has a nominal 60dB gain control range with a frequency range of 40MHz to 500MHz. The inputs of the VGA must have a DC return to ground. This can be done using a transformer with a central tap (on secondary) or an LC matching circuit with a matched impedance at the frequency of interest and near zero impedance at DC. The differential AC input impedance of the LT5506 is about 200, thus a 1:4 (impedance ratio) RF transformer with central tap can be used. In Figure 6, the evaluation board schematic is shown using a 1:4 transformer. The measured input sensitivity of this board is about -82.6dBm for a 10dB signal-to-noise ratio. In the case of an LC matching circuit, the circuit of Figure 1 can be used. In Table 1 the values are given for a range of IF frequencies. The matching circuit of Figure 1 approaches 180 phase shift between IF+ and IF- in a broad range around its center frequency. However, some amplitude mismatch occurs if the circuit is not tuned to the center frequency. This leads to reduced circuit linearity performance, because one of the inputs carries a higher signal compared to the perfectly balanced case. A 10% frequency shift from the center frequency results in about a 2dB gain difference between the IF+ and IF- inputs. This results in a 1.5dB higher IM3 contribution from the input stage which leads to a 0.75dB drop in IIP3. Moreover, the IIP2 of the circuit is also reduced which can lead to a higher second order harmonic contribution. The circuit can be driven single ended, but this is not recommended because it leads to a 3dB drop in gain and a considerable increase in IM5 and IM7 components. The single-ended noise figure increases by 4dB if one IF input is directly grounded and increases by 1.5dB if one IF input is grounded via a 1H inductor. An IF input cannot be left open or connected via a resistor to ground because this will disturb the internal biasing, reducing the gain, noise and linearity performance. For optimal performance, it is important to keep the DC impedance to ground 5506fa 7 LT5506 U U W U APPLICATIO S I FOR ATIO C3 56pF L1 56nH IF INPUT TO IF IF INPUT + TO IF + C1 10pF TO IF - TO IF - L3 120nH C1 5.6pF L2 56nH L1 15nH C2 5.6pF L2 15nH VBIAS 75 1mA 1mA IF + 75 IF - 5506 F02 5506 F01 (2a) (2b) Figure 1. IF Input Matching Network at 280MHz Figure 2a. Simplified IF Input Matching Network at 280MHz and Figure 2b. Simplified Circuit Schematic of the IF Inputs Table 1. The Component Values of Matching Network L1, L2, L3, C1, C2 and C3. This matching network can deliver equal amplitudes to the IF + and IF - inputs for a narrow frequency region, but the phase difference between the inputs will not be exactly 180 degrees. In practice, the phase shift will be around 145 degrees, depending on the quality factor of the network. This will result in a reduction in the gain. The higher the chosen quality factor, the closer the phase difference will approach 180 degrees. However, a higher quality factor will reduce bandwidth and create more loss in the matching network. For minimum board space, 0402 components are used. The measured noise figure for maximum gain with this matching network is about 8dB, and the maximum gain about 57dB. Assuming 0402 inductors with Q = 35, the insertion loss of this network is about 2.5dB. The tolerance for the components in Figure 2a can be 10% for a return loss higher than 10dB and a gain reduction due to mismatch less than 0.5dB. The measured input sensitivity for this matching network (see also Figure 11) is about -82.7dBm for a 10dB signal-to-noise ratio. fIF(MHz) L1, L2(nH) C1, C2(pF) L3(nH) C3(pF) 50 340 34 1800 820 100 159 15.9 470 220 150 106 10.6 470 220 200 80 8.0 470 220 250 64 6.4 120 56 300 53 5.3 120 56 350 45 4.5 120 56 400 40 4.0 120 56 450 35 3.5 120 56 500 32 3.2 120 56 of both IF inputs lower than 2. In the matching network of Figure 1, inductor L3 is used for supplying the DC bias current to the IF+ input. To keep the DC resistance of L3 below 2, 120nH is used. This disturbs the matching network slightly by causing the frequency where the S11 is minimal to be lower than the frequency where the amplitudes of IF+ and IF- are equal. To compensate for this, the value of coupling capacitor C3 is lowered and will contribute some correcting reactance. For low frequencies, it might not be possible to find any practical inductor value for L3 with DC resistance smaller than 2. In that case it is recommended to use a transformer with central tap. The tolerance for the components in Figure 1 can be 10% for a return loss higher than 16dB and a gain reduction due to mismatch less than 0.3dB. It is possible to simplify the input matching circuit and compromise the performance. In Figure 2a, the simplified matching network is given. The gain of the VGA is set by the voltage at the VCTRL pin. For high gain settings, both the noise figure and the input IP3 will be low. From a noise figure point of view, it is advantageous to work as closely as possible to the maximum gain point. However, if the voltage at the VCTRL pin is increased beyond the maximum gain point (where additional increase in control voltage does not give an increase in gain), the response time of the gain control circuit is increased. If control speed is crucial, a few dB of gain margin should be allowed from the highest gain point to be sure that at all temperatures, the maximum gain setting is not crossed. At low gain settings, the noise figure and the input IP3 will be high. Optionally, the control 5506fa 8 LT5506 U W U U APPLICATIO S I FOR ATIO voltage VCTRL can be set lower than 0.2V. The normal range is from VCTRL = 0.2V to 1.7V, which results in a nominal gain range from 0.9dB to 59dB. The linear-in-dB gain relation with the VCTRL voltage still holds for control voltages as low as -0.4 V. This results in an extended gain control range of -19.7dB to 59dB. The VCTRL pin is a very sensitive input because of its high input impedance and therefore should be well shielded. Signal pickup on the VCTRL pin can lead to spurs and increased noise floor in the I/Q baseband outputs. It can degrade the linearity performance and it can cause asymmetry in the two-tone test. If control speed is not important, 1F bypass capacitors are recommended between VCTRL and ground. A fast responding peak detector is connected to the VGA input, sensitive to signal levels above the signal levels where the VGA is operating in the linear range. It is active from -22dBm up to 5dBm IF input signal levels. The DC output voltage of this detector (IF DET) can be used by the baseband controller to quickly determine the presence of a strong input level at the desired channel, and adjust gain accordingly. Figure 3a shows the simplified circuit schematic of the IF DET output. I/Q Demodulators The quadrature demodulators are double balanced mixers, down-converting the amplified IF signal from the VGA into I/Q baseband signals. The quadrature LO signals are generated internally from a double frequency external CW signal. The nominal output voltage of the differential I/Q baseband signals should be set to 0.8VP-P or lower, depending on the linearity requirements. The magnitudes of I and Q are well matched and their phases are 90 apart. Quadrature LO Generator The quadrature LO generator consists of a divide-by-two circuit and LO buffers. An input signal (2xLO) with twice the desired IF signal frequency is used as the clock for the divide-by-two circuit, producing the quadrature LO signals for the demodulators. The outputs are buffered and then drive the down-converting mixers. With a fully differential approach, the quadrature LO signals are well matched. Second harmonic content (or higher order even harmonics) in the external 2xLO signal can degrade the 90 phase shift between I and Q. Therefore, such content should be VCC VCC + 400mV - 2xLO + 8k 8k 2xLO - IF DET 1k 3.8k 5506 F03 (3b) (3a) Figure 3a. Simplified Circuit Schematic of the IF DET Output and Figure 3b. The 2xLO Inputs 3.3pF 2xLO INPUT 100pF 2xLO INPUT TO 2xLO+ 39nH 2xLO INPUT 1:4 TO 2xLO- TO 2xLO+ 56 TO 2xLO+ TO 2xLO- 240 100pF 3.3pF TO 2xLO- 5506 F04 (4a) (4b) (4c) Figure 4. 2xLO Input Matching Networks for 4a) Narrow Band Tuned to 570MHz, 4b) Wide Band, 4c) Single-Ended Wide Band minimized. Figure 3b shows the simplified circuit schematic of the 2xLO inputs. Depending on the application, different 2xLO input matching networks can be chosen. In Figure 4, three examples are given. The first network provides the best 2xLO input sensitivity because it can boost up the 2xLO differential input signal using a narrow-band resonant approach. The second network gives a wide-band match, but the 2xLO input sensitivity is about 2dB lower. The third network gives a simple and less expensive wideband match, but 2xLO input sensitivity drops by about 9dB. The IF input sensitivity doesn't change significantly using either of the three 2xLO matching networks. Baseband Circuit The baseband circuit consists of I/Q hard limiters (clippers), I/Q lowpass filters and I/Q output buffers. The hard limiter operates as a linear amplifier normally. However, if a high level input temporarily overloads the linear amplifier, then the circuit will limit symmetrically, which will help to prevent the filter and output buffer from overloading. This speeds up recovery from an overload event, 5506fa 9 LT5506 U W U U APPLICATIO S I FOR ATIO which can occur during the gain settling. It also helps to reduce the high frequency spectral content at the I/Q outputs during overload. The second order integrated lowpass filters are used for filtering the down-converted baseband signals for both the I channel and the Q channel. They serve as antialiasing and pulse-shaping filters. The I/Q filters are well matched in gain response and group delay. The 3dB corner frequency is typically 8.8MHz with a group delay ripple of 5ns. The I/Q outputs can drive 2k in parallel with a maximum capacitive loading of 10pF, from all four pins to ground. The outputs are internally biased at VCC - 1.19V. Figure 5 shows the simplified output circuit schematic of the I channel or Q channel. Table 2. The Logic of Different Operating Modes EN STBY Comments Low Low Shutdown Mode Low High Standby Mode High Low or High Normal Operation Mode the EN pin and STBY pin. In both normal operating mode and standby mode, the maximum discharging current is about 300A, and the maximum charging current is more than 4mA. In Figure 5 the simplified circuit schematic of the STBY (or EN) input is shown. VCC The I/Q baseband outputs can be DC-coupled to the inputs of a baseband chip. For AC-coupled applications with large capacitors, the STBY pin can be used to pre-bias the outputs to nominal VCC - 1.19V at much reduced current. This mode draws only 3.6mA supply current. When the EN pin is then driven high (>1V), the chip is quickly switched to normal operating mode, avoiding the introduction of large charging time constants. Table 2 shows the logic of VCC IOUT+ (OR QOUT+) IOUT- (OR QOUT-) I CHANNEL (OR Q CHANNEL): DIFFERENTIAL SIGNALS FROM LPF 22k STBY (OR EN) 300A 300A 5506 F05 Figure 5. Simplified Circuit Schematic of I Channel (or Q Channel) Outputs and STBY (or EN) Input IOUT+ IOUT- QOUT+ QOUT- VCC3 C37 0.1F J1 R47 49.9 C31 1F 7 IOUT + U3 LT1809CS 6 - 4 R48 3.09k C35 4.7F R50 2k 3 2 C36 4.7F C27 0.1F R41 1k C34 0.1F R45 1k R46 3.09k R49 2k 3 R39 3.09k 2 C32 2.2pF U2 LT1809CS - 15 14 6 R44 49.9 J2 QOUT 4 C29 2.2pF 16 C30 1F 7 + R42 2k C28 0.1F C33 0.1F C38 0.1F R43 2k R40 3.09k 13 R35 VCC2 20k IOUT+ IOUT- QOUT+ QOUT- J3 IFIN C43 22nF T1, 1:4,TR-R JTX-4-10T MINI-CIRCUITS 1 6 1 2 3 4 GND IF STBY 11 2XLO+ + U1 LT5506 IF - T2, 1:4, TR-R C45 22nF JTX-4-10T MINI-CIRCUITS 12 EN 2XLO R52 240 10 2XLO - GND J4 6 9 1 R36 20k IF VCC VCTRL DET VCC 5 6 7 8 0 GND 1 = EN 2 = STBY VCC1 C22 1F C15 1nF C16 1nF VCTRL R51 100 C25 1.5pF C39 1F 5506 F04 SW1 OVERLOAD C26 NOTE: OUTPUT BUFFERS U2 AND U3 WITH ASSOCIATED 1.8pF COMPONENTS ARE INCLUDED FOR MEASUREMENT PURPOSES ONLY. BOARD NUMBER: DC468A (NARROW-BAND VERSION: DC535A) C43, C45, C22, R51, C25, C26 AND C39 ARE OPTIONAL Figure 6. Evaluation Circuit Schematic with I/Q Output Buffers 5506fa 10 LT5506 U W U U APPLICATIO S I FOR ATIO Figure 7. Component Side Silkscreen of Evaluation Board Figure 8. Component Side Layout of Evaluation Board Figure 9. Bottom Side Silkscreen of Evaluation Board Figure 10. Bottom Side Layout of Evaluation Board 5506fa Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. 11 LT5506 U W U U APPLICATIO S I FOR ATIO 15nH 1.8V RX INPUT: 2.4GHz TO 2.5GHz 1F 10pF 280MHz IF SAW BP FILTER 1nF VCC 5, 8 2 15nH 1ST LO, 2.12GHz TO 2.22GHz MAIN SYNTHESIZER AUX SYNTHESIZER BASEBAND PROCESSOR HARD I-MIXER CLIPPER LPF VGA RX FRONT END 3 16 15 I-OUTPUTS 7 IF DET 6 VCTRL 14 13 Q-OUTPUTS 0 Q-MIXER 2ND LO, 560MHz -10dBm 90 11 3.3pF HARD CLIPPER 39nH A/D A/D D/A A/D LPF f/2 12 10 LT5506 3.3pF STBY 9 EN 0,1,4 5506 F11 Figure 11. 2.4GHz to 2.5GHz Receiver Application (RX IF = 280MHz) U PACKAGE DESCRIPTIO UF Package 16-Lead Plastic QFN (4mm x 4mm) (Reference LTC DWG # 05-08-1692) 4.00 0.10 (4 SIDES) 0.72 0.05 BOTTOM VIEW--EXPOSED PAD 0.75 0.05 R = 0.115 TYP 0.55 0.20 15 16 PIN 1 TOP MARK 1 4.35 0.05 2.15 0.05 2.90 0.05 (4 SIDES) 2 2.15 0.10 (4-SIDES) PACKAGE OUTLINE (UF) QFN 0503 RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS 0.30 0.05 0.200 REF 0.30 0.05 0.65 BSC 0.00 - 0.05 0.65 BSC NOTE: 1. DRAWING CONFORMS TO JEDEC PACKAGE OUTLINE MO-220 VARIATION (WGGC) 2. ALL DIMENSIONS ARE IN MILLIMETERS 3. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE 4. EXPOSED PAD SHALL BE SOLDER PLATED RELATED PARTS PART NUMBER DESCRIPTION COMMENTS LT5500 1.8GHz to 2.7GHz Receiver Front End 1.8V to 5.25V Supply, Dual-Gain LNA, Mixer LT5502 400MHz Quadrature IF Demodulator with RSSI 1.8V to 5.25V Supply, 70MHz to 400MHz IF, 84dBm Limiting Gain, 90dB RSSI Range LT5503 1.2GHz to 2.7GHz Direct IQ Modulator and Mixer 1.8V to 5.25V Supply, Four Step RF Power Control, 120MHz Modulation Bandwidth LT5504 800MHz to 2.7GHz RF Measuring Receiver LTC5505 RF Power Detectors with >40dB Dynamic Range 2.7V to 6V Supply, 300MHz to 3.5GHz, Temperature Compensated LTC5507 100kHz to 1000MHz RF Power Detector 2.7V to 6V Supply, 40dB Dynamic Range, Temperature Compensated LT5511 High Signal Level Upconverting Mixer RF Output to 3GHz, 17dBm IIP3, Integrated LO Buffer LT5512 High Signal Level Downconverting Mixer DC-3GHz, 21dBm IIP3, Integrated LO Buffer 2.7V to 5.25V Supply, 80dB Dynamic Range, Temperature Compensated 5506fa 12 Linear Technology Corporation LT/TP 1003 1K REV A * PRINTED IN USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 FAX: (408) 434-0507 www.linear.com LINEAR TECHNOLOGY CORPORATION 2002