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LT5522EUF#TRM

LT5522EUF#TRM

  • 厂商:

    AD(亚德诺)

  • 封装:

    16-WQFN Exposed Pad

  • 描述:

    IC MIXER 400MHZ-2.7GHZ DWN 16QFN

  • 数据手册
  • 价格&库存
LT5522EUF#TRM 数据手册
LT5522 400MHz to 2.7GHz High Signal Level Downconverting Mixer U FEATURES DESCRIPTIO ■ The LT®5522 active downconverting mixer is optimized for high linearity downconverter applications including cable and wireless infrastructure. The IC includes a high speed differential LO buffer amplifier driving a double-balanced mixer. The LO buffer is internally matched for wideband, single-ended operation with no external components. ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ Internal On-Chip RF Input Transformer 50Ω Single-Ended RF and LO Ports High Input IP3: +25dBm at 900MHz +21.5dBm at 1900MHz Low Power Consumption: 280mW Typical Integrated LO Buffer: Low LO Drive Level High LO-RF and LO-IF Isolation Wide RF Frequency Range: 0.4GHz to 2.7GHz* Very Few External Components Enable Function 4.5V to 5.25V Supply Voltage Range 16-Lead (4mm × 4mm) QFN Package The RF input port incorporates an integrated RF transformer and is internally matched over the 1.2GHz to 2.3GHz frequency range with no external components. The RF input match can be shifted down to 400MHz, or up to 2.7GHz, with a single shunt capacitor or inductor, respectively. The high level of integration minimizes the total solution cost, board space and system-level variation. U APPLICATIO S ■ ■ ■ The LT5522 delivers high performance and small size without excessive power consumption. Cellular, PCS and UMTS Band Infrastructure CATV Downlink Infrastructure 2.4GHz ISM High Linearity Downmixer Applications , LTC and LT are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. *Operation over a wider frequency range is possible with reduced performance. Consult factory for information and assistance. U ■ TYPICAL APPLICATIO LO INPUT –5dBm LT5522 LO+ 1.9GHz Conversion Gain, IIP3, SSB NF and LO-RF Leakage vs LO Power LO– –10 24 22 150nH 140MHz (TYP) VGA LNA 150nH RF– EN VCC1 5522 F01 IF– BIAS/ CONTROL LTC1748 ADC 16 14 0.01µF 3.3µF –30 SSB NF –40 LO-RF 8 –50 6 IF = 140MHz LOW-SIDE LO –60 TA = 25°C VCC = 5V –70 –1 1 –9 –7 –5 –3 LO INPUT POWER (dBm) 4 5V –20 12 10 2 VCC2 IIP3 18 0 –11 LO-RF LEAKAGE (dBm) 2.7pF 100pF RF+ 1850MHz TO 1910MHz GC, SSB NF (dB), IIP3 (dBm) 20 IF+ 5522 TA01 Figure 1. High Signal Level Downmixer for Wireless Infrastructure 5522fa 1 LT5522 W W W AXI U U U W PACKAGE/ORDER I FOR ATIO U ABSOLUTE RATI GS (Note 1) NC LO– NC LO+ TOP VIEW Supply Voltage ...................................................... 5.5V Enable Voltage ............................... –0.3V to VCC + 0.3V LO Input Power ............................................... +10dBm LO+ to LO– Differential DC Voltage ......................... ±1V LO Input DC Common Mode Voltage ...................... ±1V RF Input Power ................................................ +10dBm RF+ to RF– Differential DC Voltage ........................ ±0.2V RF Input DC Common Mode Voltage ...................... ±1V Operating Temperature Range ................ –40°C to 85°C Storage Temperature Range ................. – 65°C to 125°C Junction Temperature (TJ).................................... 125°C 16 15 14 13 12 GND NC 1 RF + 2 RF – 11 IF+ 17 3 10 IF – 6 7 8 EN VCC2 NC 9 GND 5 VCC1 NC 4 UF PACKAGE 16-LEAD (4mm × 4mm) PLASTIC QFN TJMAX = 125°C, θJA = 37°C/W EXPOSED PAD (PIN 17) IS GND, MUST BE SOLDERED TO PCB ORDER PART NUMBER UF PART MARKING LT5522EUF 5522 Order Options Tape and Reel: Add #TR Lead Free: Add #PBF Lead Free Tape and Reel: Add #TRPBF Lead Free Part Marking: http://www.linear.com/leadfree/ Consult LTC Marketing for parts specified with wider operating temperature ranges. DC ELECTRICAL CHARACTERISTICS (Test circuit shown in Figure 2) VCC = 5VDC, EN = high, TA = 25°C, unless otherwise noted. (Note 3) PARAMETER Power Supply Requirements (VCC) Supply Voltage Supply Current Shutdown Current Enable (EN) Low = Off, High = On CONDITIONS TYP MAX UNITS 4.5 5 56 5.25 68 VDC mA 100 µA 0.3 VDC VDC VCC = 5V EN = Low Input High Voltage (On) Input Low Voltage (Off) Enable Pin Input Current Turn On Time MIN 3 EN = 5VDC 55 3 Turn Off Time µA µs µs 5 AC ELECTRICAL CHARACTERISTICS PARAMETER RF Input Frequency Range 75 (Notes 2, 3) (Test circuit shown in Figure 2). CONDITIONS Shunt Capacitor on Pin 3 (Low Band) No External Matching (Mid Band) Shunt Inductor on Pin 3 (High Band) MIN 400 LO Input Frequency Range IF Output Frequency Range No External Matching Requires Appropriate IF Matching 400 RF Input Return Loss LO Input Return Loss ZO = 50Ω ZO = 50Ω IF Output Return Loss LO Input Power ZO = 50Ω RF to LO Isolation 50MHz to 2700MHz TYP MAX 1200 to 2300 2700 2700 0.1 to 1000 15 13 –10 18 –5 >45 UNITS MHz MHz MHz MHz MHz dB dB 0 dB dBm dB 5522fa 2 LT5522 AC ELECTRICAL CHARACTERISTICS Cellular/PCS/UMTS downmixer application: VCC = 5V, EN = high, TA = 25°C, PRF = –7dBm (–7dBm/tone for 2-tone IIP3 tests, ∆f = 1MHz), fLO = fRF – 140MHz, PLO = –5dBm, IF output measured at 140MHz, unless otherwise noted. (Notes 2, 3) (Test circuit shown in Figure 2). PARAMETER CONDITIONS Conversion Gain RF = 450MHz, High Side LO RF = 900MHz RF = 1800MHz RF = 1900MHz RF = 2100MHz RF = 2450MHz Conversion Gain vs Temperature Input 3rd Order Intercept Single Sideband Noise Figure (Note 4) LO to RF Leakage LO to IF Leakage 2RF-2LO Output Spurious Product (fRF = fLO + fIF/2) 3RF-3LO Output Spurious Product (fRF = fLO + fIF/3) Input 1dB Compression MIN TYP MAX UNITS –2.0 –0.5 –0.2 –0.1 0.2 –0.7 dB dB dB dB dB dB TA = –40°C to 85°C RF = 450MHz, High Side LO RF = 900MHz RF = 1800MHz RF = 1900MHz RF = 2100MHz RF = 2450MHz RF = 900MHz RF = 1800MHz RF = 2100MHz RF = 2450MHz fLO = 400MHz to 2700MHz –0.02 22.3 25.0 21.8 21.5 20.0 16.8 12.5 13.9 14.3 15.6 ≤–50 dB/°C dBm dBm dBm dBm dBm dBm dB dB dB dB dBm fLO = 400MHz to 2700MHz 900MHz: fRF = 830MHz at –12dBm 1900MHz: fRF = 1830MHz at –12dBm 900MHz: fRF = 806.67MHz at –12dBm 1900MHz: fRF = 1806.67MHz at –12dBm ≤–49 –73 –60 –72 –65 dBm dBc dBc dBc dBc RF = 450MHz, High Side LO RF = 900MHz RF = 1900MHz 12.0 10.8 8.0 dBm dBm dBm –2 1150MHz CATV infrastructure application: VCC = 5V, EN = high, TA = 25°C, RF input = 1150MHz at –12dBm (–12dBm/tone for 2-tone IIP3 tests, ∆f = 1MHz), LO input swept from 1200MHz to 2200MHz, PLO = –5dBm, IF output measured from 50MHz to 1050MHz unless otherwise noted. (Note 3) (Test circuit shown in Figure 3). PARAMETER Conversion Gain CONDITIONS fLO = 1650MHz, fIF = 500MHz Input 3rd Order Intercept Single Sideband Noise Figure (Note 4) fLO = 1650MHz, fIF = 500MHz fLO = 1650MHz, fIF = 500MHz 23 14.3 dBm dB LO to RF Leakage LO to IF Leakage fLO = 1200MHz to 2200MHz fLO = 1200MHz to 2200MHz ≤–51 ≤–45 dBm dBm 2RF – LO Output Spurious Product 2RF1 – LO Output Spurious Product PRF = –12dBm (Single Tone), 50MHz ≤ fIF ≤ 900MHz 2-Tone 2nd Order Spurious Outputs 2 RF1 = 1147MHz, RF2 = 1153MHz, –15dBm/Tone LO = 1650MHz, Spurs at 644MHz, 656MHz and 650MHz ≤–63 –68 dBc dBc –68 –63 dBc dBc 2RF2 – LO Output Spurious Product (RF1 + RF2) – LO Output Spurious Product MIN TYP –0.6 MAX UNITS dB RF Input Return Loss LO Input Return Loss 950MHz to 1350MHz, ZO = 50Ω 1200MHz to 2200MHz, ZO = 50Ω >15 13 dB dB IF Output Return Loss 50MHz to 1050MHz, ZO = 50Ω 10 dB Note 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired. Note 2: 450MHz, 900MHz and 2450MHz performance measured with the following external RF input matching. 450MHz: C5 = 8.2pF, 5mm away from Pin 3 on the 50Ω input line. 900MHz: C5 = 2.2pF at Pin 3. 2450MHz: L3 = 3.9nH at Pin 3. See Figure 2. Note 3: Specifications over the –40°C to 85°C operating temperature range are assured by design, characterization and correlation with statistical process controls. Note 4: SSB Noise Figure measurements performed with a small-signal noise source and bandpass filter on RF input, and no other RF signal applied. 5522fa 3 LT5522 U W TYPICAL AC PERFOR A CE CHARACTERISTICS Mid-band RF (no external RF matching) VCC = 5V, EN = High, TA = 25°C, PRF = –7dBm (–7dBm/tone for 2-tone IIP3 tests, ∆f = 1MHz), PLO = –5dBm, IF output measured at 140MHz, unless otherwise noted. (Test circuit shown in Figure 2). Conv Gain, IIP3 and SSB NF vs RF Frequency (High Side LO) Conv Gain, IIP3 and SSB NF vs RF Frequency (Low Side LO) 23 19 17 SSB NF 15 13 7 5 3 1 –1 1300 1500 19 –45 17 SSB NF 15 13 11 9 7 1900 2100 1700 RF FREQUENCY (MHz) 1500 1900 2100 1700 RF FREQUENCY (MHz) GC AND SSB NF (dB), IIP3 (dBm) IIP3 GC (dB), IIP3 (dBm) 12 10 8 6 4 2 GC LOW SIDE LO HIGH SIDE LO 0 fIF = 140MHz –2 0 25 50 –50 –25 TEMPERATURE (°C) 20 IIP3 18 16 16 SSB NF 14 12 25°C 85°C –40°C fLO = 1660MHz fIF = 140MHz 10 8 6 4 20 18 LOW SIDE LO 18 GC AND SSB NF (dB), IIP3 (dBm) GC (dB), IIP3 (dBm) HIGH SIDE LO IIP3 14 12 10 8 6 LOW SIDE LO HIGH SIDE LO 6 100 5522 G07 GC 2 –9 –1 –7 –5 –3 LO INPUT POWER (dBm) –2 1 4.5 16 5522 G06 10 0 IIP3 SSB NF 12 25°C 85°C –40°C fLO = 1960MHz fIF = 140MHz 10 8 6 2 IF OUT (RF = 1900MHz) –10 14 4 5.5 5 5.25 4.75 SUPPLY VOLTAGE (V) IF OUT, 2 × 2 and 3 × 3 Spurs vs RF Input Power (Single Tone) GC –2 –11 –20 –30 –40 –60 –70 –9 –1 –7 –5 –3 LO INPUT POWER (dBm) 1 5522 G08 3RF-3LO (RF = 1806.67MHz) –50 –80 0 0 75 8 Conv Gain, IIP3 and SSB NF vs LO Power (RF = 2100MHz) 20 fIF = 140MHz –2 –50 0 25 50 –25 TEMPERATURE (°C) 10 5522 G05 Conv Gain and IIP3 vs Temperature (RF = 2100MHz) GC 12 0 –2 –11 100 25°C 85°C –40°C fLO = 1660MHz fIF = 140MHz 14 4 GC 2 0 75 IIP3 18 5522 G04 2 Conv Gain and IIP3 vs Supply Voltage (RF = 1800MHz) 22 20 14 4 5522 G03 22 16 16 –90 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) 2300 Conv Gain, IIP3 and SSB NF vs LO Power (RF = 1800MHz) 22 18 –70 5522 G02 Conv Gain and IIP3 vs Temperature (RF = 1800MHz) LOW SIDE LO HIGH SIDE LO LO-IF –65 –85 GC 5522 G01 20 –55 –60 –80 3 –1 1300 2300 LO-RF –50 –75 5 1 GC T = 25°C –35 f A = 140MHz IF –40 GC (dB), IIP3 (dBm) 9 TA = 25°C fIF = 140MHz TA = 25°C fIF = 140MHz OUTPUT POWER (dBm) 11 IIP3 21 IIP3 GC AND SSB NF (dB), IIP3 (dBm) GC AND SSB NF (dB), IIP3 (dBm) 21 LO Leakage vs LO Frequency –30 LO LEAKAGE (dBm) 23 2RF-2LO (RF = 1830MHz) TA = 25°C fLO = 1760MHz fIF = 140MHz –90 –21 –18 –15 –12 –9 –6 –3 0 3 RF INPUT POWER (dBm) 6 9 5522 G09 5522fa 4 LT5522 U W TYPICAL AC PERFOR A CE CHARACTERISTICS Low-band RF (C5 = 2.2pF) and high-band RF (L3 = 3.9nH) VCC = 5V, EN = High, TA = 25°C, PRF = –7dBm (–7dBm/tone for 2-tone IIP3 tests, ∆f = 1MHz), PLO = –5dBm, IF output measured at 140MHz, unless otherwise noted. (Test circuit shown in Figure 2). 26 17 16 24 15 22 13 IIP3 20 12 GC (dB) 18 8 16 SSB NF 6 14 HIGH SIDE LO 4 12 LOW SIDE LO 2 0 GC –2 600 700 900 1000 1100 800 RF FREQUENCY (MHz) HIGH SIDE LO IIP3 7 16 5 14 3 8 –1 12 GC LOW SIDE LO HIGH SIDE LO fIF = 140MHz –3 –50 –25 25 50 0 TEMPERATURE (°C) –90 16 14 12 –100 –18 –15 –12 –9 –6 –3 0 3 6 RF INPUT POWER (dBm) –60 LO-RF 7 5 –80 –1 8 –85 –1 6 –90 400 0 600 1000 1200 800 LO FREQUENCY (MHz) 16 SSB NF 8 6 2 0 GC –2 2200 2300 2500 2600 2400 RF FREQUENCY (MHz) 12 –80 16 IIP3 9 fLO = 2310MHz fIF = 140MHz 7 5 3 –90 1 –100 –1 –110 2700 5522 G16 18 11 –70 TA = 25°C fIF = 140MHz LOW SIDE LO 4 17 14 –60 LO-IF High Band Conv Gain, IIP3 and SSB NF vs LO Power (RF = 2450MHz) 13 –50 –3 –50 6 5.5 5522 G15 15 –40 LO-RF 10 4.75 5 5.25 SUPPLY VOLTAGE (V) GC 20 IIP3 19 18 17 SSB NF 10 8 15 25°C 85°C –40°C fLO = 2310MHz fIF = 140MHz 6 4 2 16 GC 14 13 12 0 –25 25 50 0 TEMPERATURE (°C) 75 100 5522 G17 –2 –11 SSB NF (dB) 12 8 4.5 –20 –30 14 10 –3 –10 LO LEAKAGE (dBm) 14 1400 GC (dB), IIP3 (dBm) IIP3 16 12 High Band Conv Gain and IIP3 vs Temperature (RF = 2450MHz) GC (dB), IIP3 (dBm) 18 18 GC 5522 G14 High Band Conv Gain, IIP3, SSB NF and LO Leakage vs RF Frequency 20 20 25°C 85°C –40°C fLO = 760MHz fIF = 140MHz 9 3 –75 1 22 11 1 –5 –3 –1 –7 LO INPUT POWER (dBm) 24 13 –55 –70 26 IIP3 15 LO-IF –65 12 Low Band Conv Gain and IIP3 vs Supply Voltage (RF = 900MHz) –45 –50 9 5522 G12 10 –9 TA = 25°C fLO = 760MHz 17 5522 G13 GC AND SSB NF (dB), IIP3 (dBm) –80 1 –3 –11 2RF-2LO (RF = 830MHz) –70 IIP3 (dBm) 18 GC –60 GC (dB) 20 GC (dB) 22 11 SSB NF (dB), IIP3 (dBm) 13 SSB NF 3RF-3LO (RF = 806.67MHz) –50 8 –30 TA = 25°C –35 f = 140MHz IF –40 PLO = –5dBm LO LEAKAGE (dBm) 24 5 –30 –40 LO Leakage vs LO Frequency (Low Band RF Match) 15 3 –20 10 6 100 75 IF OUT (RF = 900MHz) 5522 G11 26 7 –10 18 1 17 25°C 85°C –40°C fLO = 760MHz fIF = 140MHz 22 9 Low Band Conv Gain, IIP3 and SSB NF vs LO Power (RF = 900MHz) 9 0 20 5522 G10 IIP3 10 24 11 10 6 1200 26 IIP3 (dBm) 10 TA = 25°C fIF = 140MHz SSB NF (dB), IIP3 (dBm) LOW SIDE LO GC (dB) HIGH SIDE LO LOW SIDE LO OUTPUT POWER (dBm) 18 14 Low Band IF OUT, 2 × 2 and 3 × 3 Spurs vs RF Input Power (Single Tone) Low Band Conv Gain and IIP3 vs Temperature (RF = 900MHz) Low Band Conv Gain, IIP3 and SSB NF vs RF Frequency 11 10 –9 –5 –3 –1 –7 LO INPUT POWER (dBm) 1 5522 G18 5522fa 5 LT5522 U W TYPICAL AC PERFOR A CE CHARACTERISTICS CATV infrastructure downmixer VCC = 5V, EN = High, TA = 25°C, PRF = 1150MHz at –12dBm (–12dBm/tone for 2-tone IIP3 tests, ∆f = 1MHz), LO swept from 1200MHz to 2200MHz, PLO = –5dBm, IF output measured from 50MHz to 1050MHz, unless otherwise noted. (Test circuit shown in Figure 3) IIP3 SSB NF 25°C 85°C –40°C fRF = 1150MHz PLO = –5dBm GC LO Leakage vs LO Frequency –50 –10 –55 –20 PLO = –8, –5 AND –2dBm 25°C –60 85°C LO LEAKAGE (dBm) 26 24 22 20 18 16 14 12 10 8 6 4 2 0 –2 –4 2RF-LO Spur vs IF Output Frequency (PRF = –12dBm) RELATIVE SPUR LEVEL (dBc) GC AND SSB NF (dB), IIP3 (dBm) Conv Gain, IIP3 and SSB NF vs IF Output Frequency –65 –70 450 650 250 850 IF OUTPUT FREQUENCY (MHz) 1050 50 LO-RF –50 LO-IF –70 1200 1050 250 450 650 850 IF OUTPUT FREQUENCY (MHz) 1400 GC AND SSB NF (dB), IIP3 (dBm) Conv Gain, IIP3 and SSB NF vs Temperature (IF = 500MHz) SSB NF 25°C 85°C –40°C fLO = 1650MHz fRF = 1150MHz –1 –7 –3 –5 LO INPUT POWER (dBm) 1 23 21 19 17 15 13 11 9 7 5 3 1 –1 –3 –50 IIP3 SSB NF fLO = 1650MHz PLO = –5dBm fRF = 1150MHz GC –25 0 25 50 TEMPERATURE (°C) 0 OUTPUT POWER (dBm/TONE) IF OUTPUT POWER AND SPURIOUS (dBm) 10 IF OUT (500MHz) TA = 25°C fLO = 1650MHz fRF = 1150MHz –30 –40 –50 –60 –70 –80 2RF-2LO (1000MHz) 2RF-LO (650MHz) 3RF-2LO (150MHz) –90 –100 –21 –17 –5 –13 –9 –1 RF INPUT POWER (dBm) –10 –20 7 5522 G24 TA = 25°C fLO = 1650MHz fRF = 1150MHz IF OUT –30 –40 –50 IM3 –60 –70 –80 3 100 IF Output Power, IM3 and IM5 vs RF Input Power (Two Input Tones) 10 –10 75 5522 G23 IF Output Power and Spurious Products vs RF Input Power (Single Tone) –20 2200 5522 G21 5522 G22 0 1600 1800 2000 LO FREQUENCY (MHz) 5522 G20 Conv Gain, IIP3 and SSB NF vs LO Power (IF = 500MHz) GC AND SSB NF (dB), IIP3 (dBm) –40 –60 5522 G19 25 23 21 IIP3 19 17 15 13 11 9 7 5 3 G C 1 –1 –3 –9 –11 –30 –40°C –75 –80 50 TA = 25°C PLO = –5dBm IM5 –90 –21 –18 –15 –12 –9 –6 –3 0 RF INPUT POWER (dBm/TONE) 3 5522 G25 5522fa 6 LT5522 U W TYPICAL AC PERFOR A CE CHARACTERISTICS 450MHz Application (C5 = 8.2pF, 5mm away from Pin 3) VCC = 5V, EN = High, TA = 25°C, PRF = –7dBm (–7dBm/tone for 2-tone IIP3 tests, ∆f = 1MHz), PLO = –5dBm, IF output measured at 140MHz, unless otherwise noted. (Test circuit shown in Figure 2) Single Tone IF Output Power and Conv Gain vs RF Input Power (RF = 450MHz) 24 22 IIP3 20 18 16 14 SSB NF 12 10 8 6 HIGH SIDE LO 4 TA = 25°C 2 fIF = 140MHz GC 0 –2 –4 350 370 390 410 430 450 470 490 510 530 550 RF INPUT FREQUENCY (MHz) Conv Gain, IIP3 and SSB NF vs LO Input Power (RF = 450MHz) 10 7 GC (dB), IIP3 (dBm), SSB NF (dB) IF OUTPUT POWER (dBm), GC (dB) GC (dB), IIP3 (dBm) Conv Gain, IIP3 and SSB NF vs RF Frequency (High Side LO) IFOUT 4 1 GC –2 –5 –8 HIGH SIDE LO TA = 25°C fIF = 140MHz –11 –14 –12 –9 –6 –3 0 3 6 RF INPUT POWER (dBm) 9 12 24 22 IIP3 20 18 16 14 12 10 8 6 4 2 GC 0 –2 –4 –11 –9 SSB NF –7 –5 25°C 85°C –40°C HIGH SIDE LO TA = 25°C fIF = 140MHz –3 –1 1 LO INPUT POWER (dBm) 5522 G26 5522 G28 5522 G27 U W TYPICAL DC PERFOR A CE CHARACTERISTICS Supply Current vs Supply Voltage (Test circuit shown in Figure 2) Shutdown Current vs Supply Voltage 100 57.0 SHUTDOWN CURRENT (µA) SUPPLY CURRENT (mA) 56.5 56.0 25°C 55.5 85°C –40°C 55.0 54.5 54.0 85°C 10 25°C 1 –40°C 53.5 53.0 4.5 0.1 5 4.75 5.25 SUPPLY VOLTAGE (V) 5.5 5522 G29 4.5 4.75 5 5.25 SUPPLY VOLTAGE (V) 5.5 5522 G30 5522fa 7 LT5522 U U U PI FU CTIO S externally connected to the VCC1 pin and decoupled with 0.01µF and 3.3µF capacitors. NC (Pins 1, 4, 8, 13, 16): Not Connected Internally. These pins should be grounded on the circuit board for improved LO to RF and LO to IF isolation. GND (Pins 9, 12): Ground. These pins are internally connected to the backside ground for improved isolation. They should be connected to RF ground on the circuit board, although they are not intended to replace the primary grounding through the backside contact of the package. RF+, RF– (Pins 2, 3): Differential Inputs for the RF Signal. The RF input signal should be applied to the RF– pin (Pin 3) and the RF+ pin (Pin 2) must be connected to ground. These pins are the primary side of the RF input balun which has low DC resistance. If the RF source is not DC blocked, then a series blocking capacitor must be used. IF–, IF+ (Pins 10, 11): Differential Outputs for the IF Signal. An impedance transformation may be required to match the outputs. These pins must be connected to VCC through impedance matching inductors, RF chokes or a transformer center-tap. EN (Pin 5): Enable Pin. When the input enable voltage is higher than 3V, the mixer circuits supplied through Pins 6, 7, 10 and 11 are enabled. When the input enable voltage is less than 0.3V, all circuits are disabled. Typical input EN pin current is 55µA for EN = 5V and 0µA when EN = 0V. The EN pin should not be left floating. Under no conditions should the EN pin voltage exceed VCC + 0.3V, even at start-up. LO–, LO+ (Pins 14, 15): Differential Inputs for the Local Oscillator Signal. The LO input can also be driven single ended by connecting one input to ground. These pins are internally matched for 50Ω single-ended operation. If the LO source is not AC-coupled, then a series blocking capacitor must be used. VCC1 (Pin 6): Power Supply Pin for the LO Buffer Circuits. Typical current consumption is 22mA. This pin should be externally connected to the VCC2 pin and decoupled with 0.01µF and 3.3µF capacitors. Exposed Pad (Pin 17): Circuit Ground Return for the Entire IC. This must be soldered to the printed circuit board ground plane. VCC2 (Pin 7): Power Supply Pin for the Bias Circuits. Typical current consumption is 4mA. This pin should be W BLOCK DIAGRA 2 3 DOUBLE BALANCED MIXER RF+ GND 12 IF + LINEAR AMPLIFIER RF – IF– GND 11 10 9 LIMITER HIGH SPEED LO BUFFER 15 14 LO+ LO– BIAS EN 6 VCC1 EXPOSED PAD 17 7 5 VCC2 5522 BD 5522fa 8 LT5522 TEST CIRCUITS LO IN 400MHz TO 2700MHz 0.018 16 1 2 NC NC LO 15 14 + – LO NC RF+ 0.018 GND IF+ 12 3 OPTIONAL SHUNT REACTANCE USED FOR LOW BAND OR HIGH BAND RF MATCH ONLY L3 (HIGH BAND) C5 OR (LOW BAND) 4 C4 RF– NC IF– EN VCC1 VCC2 5 6 L1 11 LT5522 RF IN 400MHz TO 2700MHz NC 7 εR = 4.4 0.062 13 GND 10 RF GND BIAS GND 3 T1 4 C3 2 L2 • • 1 5 IF OUT 140MHz 9 8 EN VCC C1 C2 GND 5522 F02 REF DES VALUE SIZE PART NUMBER C1 0.01µF 0402 Murata GRP155R71C103K REF DES VALUE SIZE PART NUMBER L1, L2 82nH 0603 Coilcraft 0603CS-82NX C2 3.3µF 1206 Taiyo Yuden LMK316BJ475ML T1 4:1 C3 100pF 0402 Murata GRP1555C1H101J C5 2.2pF 0402 Murata GRP1555C1H1R5C (For Low Band Operation Only) C4 1.5pF 0402 Murata GRP1555C1H1R5C L3 3.9nH 0402 Coilcraft 0402CS-3N9X (For High Band Operation Only) M/A-Com ETC4-1-2 (2-800MHz) Figure 2. Test Schematic for Downmixer Application (140MHz IF) (DC689A) LO IN 1200MHz TO 2200MHz 16 1 2 NC NC 15 LO+ 14 LO– 13 NC GND 12 11 IF+ RF+ T1 L1 C6 4 3 C3 2 LT5522 RF IN 1150MHz (TYP) 3 C5 C7 RF– IF– 1 10 5 L2 4 NC EN VCC1 VCC2 5 6 NC 7 GND IF OUT 50MHz TO 1000MHz 9 8 EN VCC C1 C2 GND 5522 F03 REF DES VALUE SIZE PART NUMBER C1 0.01µF 0402 Murata GRP155R71C103K C2 3.3µF 1206 Taiyo Yuden LMK316BJ475ML C3, C6, C7 330pF 0402 Murata GRP155R71H331K REF DES VALUE C5 1.5pF L1, L2 18nH T1 4:1 SIZE PART NUMBER Murata GRP1555C1H1R5C 0402 Toko LL1005-FH18NJ M/A-Com MABAES0054 (5-1000MHz) Figure 3. Test Schematic for CATV Infrastructure Downmixer Application (50MHz to 1000MHz IF) (DC651A) 5522fa 9 LT5522 U W U U APPLICATIO S I FOR ATIO Introduction RF Input Port The LT5522 consists of a high linearity double-balanced mixer, RF buffer amplifier, high speed limiting LO buffer amplifier and bias/enable circuits. The IC has been optimized for downconverter applications where the RF input signal is in the 400MHz to 2.7GHz range and the LO signal is in the 400MHz to 2.7GHz range. Operation over a wider RF input frequency range is possible with reduced performance. The mixer’s RF input, shown in Figure 4, consists of an integrated balun and a high linearity differential amplifier. The primary terminals of the balun are connected to the RF+ and RF– pins (Pins 2 and 3, respectively). The secondary side of the balun is internally connected to the amplifier’s differential inputs. For single-ended operation, the RF+ pin is grounded and the RF– pin becomes the RF input. It is also possible to ground the RF– pin and drive the RF+ pin, although the LO to RF isolation will degrade slightly. The IF output can be matched for IF frequencies as low as 100kHz or as high as 1GHz. The RF, LO and IF ports are all differential, although the RF and LO ports are internally matched for single-ended drive as shown in Figure 2. The LT5522 is characterized and production-tested with singleended RF and LO drive. Low side or high side LO injection can be used. Two evaluation boards are available. The standard board is intended for most applications, including cellular, PCS, UMTS and 2.4GHz. A schematic is shown in Figure 2 and the board layout is shown in Figure 18. The 140MHz IF output frequency on the standard board is easily changed by modifying the IF matching elements. The second board, intended for CATV applications, incorporates a wideband IF output balun. The CATV evaluation schematic is shown in Figure 3 and the board layout is shown in Figure 19. The RF source must be AC-coupled since one terminal of the balun’s primary is grounded. If the RF source has DC voltage present, then a coupling capacitor must be used in series with the RF input pin. As shown in Figure 5, the RF input return loss, with no external matching, is greater than 10dB from 1.2GHz to 2.4GHz. The RF input match can be shifted down in frequency by adding a shunt capacitor at the RF input. Two examples are plotted in Figure 5. A 2.2pF capacitor, located near Pin 3, produces a 900MHz match. An 8.2pF capacitor, located 5mm away from Pin 3 (on the 50Ω line), produces a 450MHz match. The RF input match can also be shifted up in frequency by adding a shunt inductor near Pin 3. One example is plotted in Figure 5, where a 3.9nH inductor produces a 2.3GHz to 2.8GHz match. 0 LT5522 L3 = 3.9nH (HIGH BAND) 2 RF IN 3 RF+ RF – TO MIXER C5 OPTIONAL SHUNT REACTANCE FOR LOW BAND OR HIGH BAND MATCHING (C5 OR L3) PORT RETURN LOSS (dB) –5 –10 –15 C5 = 8.2pF L = 5mm (450MHz) –20 –25 5522 F04 Figure 4. RF Input Schematic –30 0.2 C5 = 2.2pF (900MHz) 0.7 NO EXTERNAL MATCH 2.7 1.2 1.7 2.2 RF FREQUENCY(GHz) 3.2 3.7 5522 F05 Figure 5. RF Input Return Loss 5522fa 10 LT5522 U W U U APPLICATIO S I FOR ATIO 0 RF input impedance and S11 versus frequency are shown in Table 1. The listed data is referenced to the RF– pin with the RF+ pin grounded (no external matching). This information can be used to simulate board-level interfacing to an input filter, or to design a broadband input matching network. PORT RETURN LOSS (dB) –5 A broadband RF input match is easily realized using the shunt inductor/series capacitor network shown in Figure 6. This network provides good return loss at low and high frequencies simultaneously, with reasonable midband return loss. As shown in Figure 7, the RF input return loss is greater than 12dB from 715MHz to 2.3GHz using the element values shown in Figure 6. The input match is optimum at 850MHz and 1900MHz, ideal for triband GSM applications. –10 –15 –20 –25 1E8 5E9 1E9 RF FREQUENCY (Hz) 5522 F07 Figure 7. RF Input Return Loss Using Wideband Matching Network LO Input Port Table 1. RF Port Input Impedance vs Frequency S11 FREQUENCY (MHZ) INPUT IMPEDANCE MAG ANGLE 50 10.4 + j2.6 0.660 173.5 500 19.5 + j20.6 0.507 129.5 700 24.1 + j24.2 0.454 118.7 900 28.6 + j26.1 0.407 111.1 1100 33.7 + j26.2 0.353 104.4 1300 39.5 + j24.3 0.285 98.2 1500 45.6 + j18.9 0.199 92.0 1700 50.2 + j9.7 0.096 83.0 1900 50.5 – j2.2 0.023 –76.0 2100 45.6 – j13.2 0.143 –100.7 2300 38.0 – j19.9 0.259 –108.3 2500 30.4 – j22.8 0.360 –114.8 2700 24.5 – j23.0 0.440 –120.7 3000 18.7 – j20.9 0.525 –129.4 The LO buffer amplifier consists of high speed limiting differential amplifiers, designed to drive the mixer quad for high linearity. The LO+ and LO– pins are designed for single-ended drive, although differential drive can be used if a differential LO source is available. A schematic is shown in Figure 8. Measured return loss is shown in Figure 9. The LO source must be AC-coupled to avoid forward biasing the ESD diodes. If the LO source has DC voltage present, then a coupling capacitor must be used in series with the LO input pin. LO input impedance and S11 versus frequency are shown in Table 2. The listed data is referenced to the LO+ pin with the LO– pin grounded. LT5522 LT5522 2 RFIN 3 L3 10nH C5 3.3pF 14 RF+ LO IN RF – 15 15pF LO – LO+ 480Ω 15pF TO MIXER 5522 F06 5522 F08 Figure 6. Wideband RF Input Matching Figure 8. LO Input Schematic 5522fa 11 LT5522 U W U U APPLICATIO S I FOR ATIO For IF frequencies below 140MHz, an 8:1 transformer connected across the IF pins will perform impedance transformation and provide a single-ended 50Ω output. No other matching is required. Measured performance using this technique is shown in Figure 12. Output return loss is shown in Figure 13. 0 PORT RETURN LOSS (dB) –5 –10 –15 –20 –25 –30 1E8 IF+ LT5522 15mA 4:1 11 1E9 LO FREQUENCY (Hz) L1 460Ω 5E9 C4 0.5pF 5522 F09 VCC VCC L2 10 Figure 9. LO Input Return Loss IF OUT IF– 15mA 5522 F10 Table 2. LO Port Input Impedance vs Frequency Figure 10. IF Output with External Matching S11 FREQUENCY (MHZ) INPUT IMPEDANCE MAG ANGLE 100 200.5 – j181.0 0.763 –14.3 250 55.9 – j61.6 0.505 –54.4 500 44.6 – j27.7 0.286 –84.8 1000 37.9 – j7.8 0.163 –142.1 1500 33.6 – j1.8 0.197 –172.3 2000 31.0 – j0.3 0.234 –178.9 2500 30.6 – j0.4 0.240 –178.4 3000 31.8 – j1.0 0.223 –176.0 + 0.7nH IF 11 LT5522 RS 400Ω 1pF 0.7nH 10 IF– 5522 F11 Figure 11. IF Output Small-Signal Model 24 8 7 The IF outputs, IF+ and IF–, are internally connected to the collectors of the mixer switching transistors (see Figure 10). Both pins must be biased at the supply voltage, which can be applied through the center-tap of a transformer or through matching inductors. Each IF pin draws 15mA of supply current (30mA total). For optimum single-ended performance, these differential outputs should be combined externally through an IF transformer. Both evaluation boards include IF transformers for impedance transformation and differential to singleended transformation. 6 The IF output impedance can be modeled as 400Ω in parallel with 1pF. An equivalent small-signal model (including bondwire inductance) is shown in Figure 11. For most applications, the bondwire inductance can be ignored. RF = 1800MHz 22 IIP3 20 18 GC (dB) 5 LOW SIDE LO PLO = –5dBm 4 16 3 14 2 12 1 RF = 1800MHz 0 10 GC 8 RF = 900MHz –1 0 20 40 60 80 100 IF FREQUENCY (MHz) IIP3 (dBm) IF Output Port RF = 900MHz 120 6 140 5522 F12 Figure 12. Typical Conversion Gain and IIP3 Using an 8:1 IF Transformer 5522fa 12 LT5522 U W U U APPLICATIO S I FOR ATIO For optimum linearity, C4 must be located close to the IF pins. Excessive trace length or inductance between the IF pins and C4 will increase the amplitude of the image output and reduce voltage swing headroom for the desired IF frequency. High Q wire-wound chip inductors (L1 and L2) improve the mixer’s conversion gain by a few tenths of a dB, but have little effect on linearity. This matching network is most suitable for IF frequencies of 40MHz or above. Below 40MHz, the value of the series inductors (L1 and L2) is high, and could cause stability problems, depending on the inductor value and parasitics. Therefore, the 8:1 transformer technique is recommended for low IF frequencies. Suggested matching network values for several IF frequencies are listed in Table 3. Measured output return losses for the 140MHz match and the wideband CATV match are plotted in Figure 13. Table 3. IF Matching Element Values (See Figure 10) IF FREQUENCY (MHz) L1, L2 (nH) C4 (pF) IF TRANSFORMER 2-140 Short — TC8-1 (8:1) 70 220 4.7 ETC4-1-2 (4:1) 140 82 1.5 240 56 0.5 380 39 — 50-1000 (CATV) 18 — MABAES0054 (4:1) For fully differential IF architectures, the IF transformer can be eliminated. As shown in Figure 14, supply voltage to the mixer’s IF pins is applied through matching inductors in a bandpass IF matching network. The values of L1, L2 and C4 are calculated to resonate at the desired IF frequency with a quality factor that satisfies the required IF bandwidth. The L and C values are then adjusted to 0 –5 PORT RETURN LOSS (dB) Higher linearity and lower LO-IF leakage can be realized by using the simple, three element lowpass matching network shown in Figure 10. Matching elements C4, L1 and L2 form a 400Ω to 200Ω lowpass matching network which is tuned to the desired IF frequency. The 4:1 transformer then transforms the 200Ω differential output to 50Ω single-ended. The value of C4 is reduced by 1pF to account for the equivalent internal capacitance. –10 –15 –20 –25 1E7 1E9 1E8 IF FREQUENCY (Hz) 5522 F13 240MHz MATCH LUMPED ELEMENT BRIDGE BALUN 140MHz MATCH (82nH/1.5pF) 4:1 BALUN LOW FREQ MATCH (NO IF MATCHING) 8:1 BALUN 50MHz TO 1000MHz (18nH/0pF) 4:1 CATV BALUN Figure 13. Typical IF Output Return Losses for Various Matching Techniques IF + C3 L1 SAW FILTER IF AMP C4 IF– L2 5522 F14 VCC Figure 14. Bandpass IF Matching for Differential IF Architectures account for the mixer’s internal 1pF capacitance and the SAW filter’s input capacitance. In this case, the differential IF output impedance is 400Ω, since the bandpass network does not transform the impedance. For low cost applications, it is possible to replace the IF transformer with a lumped-element network which produces a single-ended 50Ω output. One approach is shown in Figure 15, where L1, L2, C4 and C6 form a narrowband bridge balun. The L and C values are calculated to realize a 180 degree phase shift at the desired IF frequency using the equations listed below. Inductor L4 is calculated to cancel the internal 1pF capacitance. L3 also supplies bias voltage to the IF+ pin. Low cost multilayer chip inductors are adequate for L1 and L2. A high Q wire-wound chip 5522fa 13 LT5522 U W U U APPLICATIO S I FOR ATIO L4 390nH L2 100nH C7 1000pF C6 4.7pF IF OUT 50Ω C3 1000pF VCC 5522 F15 16 10 –10 SSB NF –30 12 LO-IF LOW SIDE LO PLO = –5dBm IF = 240MHz VCC = 5VDC TA = 25°C 8 4 0 1600 inductor is recommended for L4 to preserve conversion gain and minimize DC voltage drop to the IF+ pin. C7 is a DC blocking capacitor and C3 is a bypass capacitor. 1700 1800 1900 2000 2100 RF INPUT FREQUENCY (MHz) –50 –70 –90 2200 5522 F16 Figure 16. Typical Performance Using a Narrowband Bridge Balun (Swept RF) L1, L2 = 21 GC (dB), IIP3 (dBm), SSB NF (dB) 19 10 0 IIP3 17 15 –10 SSB NF –20 13 11 –30 LO-IF 9 7 5 3 1 GC –40 LOW SIDE LO –50 PLO = –5dBm RF = 1900MHz –60 VCC = 5VDC –70 TA = 25°C –80 LO-IF LEAKAGE (dBm) The narrowband bridge IF balun delivers good conversion gain, linearity and noise figure over a limited IF bandwidth. LO-IF leakage is approximately –32dBm, which is 17dB worse than that obtained with a transformer. Typical IF output return loss is plotted in Figure 13 for comparison with other matching methods. Typical mixer performance versus RF input frequency for 240MHz IF matching is shown in Figure 16. Typical performance versus IF output frequency for the same circuit is shown in Figure 17. The results in Figure 17 show that the usable IF bandwidth is approximately ±25MHz, assuming tight tolerance matching components. Contact the factory for application assistance with this circuit. IIP3 GC Figure 15. Narrowband Bridge IF Balun (240MHz Example) ZIF • ZOUT (ZIF = 400) ω 1 C4, C6 = ω • ZIF • ZOUT 20 LO-IF LEAKAGE (dBm) IF – 30 24 GC (dB), IIP3 (dBm), SSB NF (dB) IF+ C4 L1 4.7pF 100nH –90 –1 –100 190 200 210 220 230 240 250 260 270 280 290 IF OUTPUT FREQUENCY (MHz) 5522 F17 Figure 17. Typical Performance Using a Narrowband Bridge Balun (Swept IF) 5522fa 14 LT5522 U PACKAGE DESCRIPTIO UF Package 16-Lead Plastic QFN (4mm × 4mm) (Reference LTC DWG # 05-08-1692) 0.72 ±0.05 4.35 ± 0.05 2.15 ± 0.05 2.90 ± 0.05 (4 SIDES) PACKAGE OUTLINE 0.30 ±0.05 0.65 BSC RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS BOTTOM VIEW—EXPOSED PAD 4.00 ± 0.10 (4 SIDES) 0.75 ± 0.05 R = 0.115 TYP 15 PIN 1 NOTCH R = 0.20 TYP OR 0.35 × 45° CHAMFER 16 0.55 ± 0.20 PIN 1 TOP MARK (NOTE 6) 1 2.15 ± 0.10 (4-SIDES) 2 (UF16) QFN 10-04 0.200 REF 0.00 – 0.05 0.30 ± 0.05 0.65 BSC NOTE: 1. DRAWING CONFORMS TO JEDEC PACKAGE OUTLINE MO-220 VARIATION (WGGC) 2. DRAWING NOT TO SCALE 3. ALL DIMENSIONS ARE IN MILLIMETERS 4. 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 5. EXPOSED PAD SHALL BE SOLDER PLATED 6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE TOP AND BOTTOM OF PACKAGE 5522fa 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. 15 LT5522 U W U U APPLICATIO S I FOR ATIO Figure 18. Standard Evaluation Board Layout Figure 19. CATV Evaluation Board Layout RELATED PARTS PART NUMBER ® LTC 1748 DESCRIPTION COMMENTS 14-Bit, 80Msps, Low Noise ADC 76.3dB SNR, 90dB SFDR LTC2222/LTC2223 12-Bit, 105Msps/80Msps ADC Low Power 775MHz BW S/H, 61dB SNR, 75dB SFDR ±0.5V or ±1V Input LT5504 800MHz to 2.7GHz RF Measuring Receiver 80dB Dynamic Range, Temperature Compensated, 2.7V to 5.5V Supply LTC5505 300MHz to 3.5GHz RF Power Detector >40dB Dynamic Range, Temperature Compensated, 2.7V to 6V Supply LT5506 500MHz Quadrature IF Demodulator with VGA 1.8V to 5.25V Supply, 40MHz to 500MHz IF, –4dB to 57dB Linear Power Gain LTC5507 100kHz to 1GHz RF Power Detector 48dB Dynamic Range, Temperature Compensated, 2.7V to 6V Supply LTC5508 300MHz to 7GHz RF Power Detector SC70 Package LTC5509 300MHz to 3GHz RF Power Detector 36dB Dynamic Range, SC70 Package LT5511 High Signal Level Up Converting Mixer RF Output to 3GHz, 17dBm IIP3, Integrated LO Buffer LT5512 High Signal Level Active Mixer 1kHz-3GHz, 20dBm IIP3, Integrated LO Buffer, HF/VHF/UHF Optimized LT5515 1.5GHz to 2.5GHz Direct Conversion Demodulator 20dBm IIP3, Integrated LO Quadrature Generator LT5516 0.8GHz to 1.5GHz Direct Conversion Quadrature Demodulator 21.5dBm IIP3, Integrated LO Quadrature Generator LT5521 Very High Linearity Up Converting Mixer 3.7GHz Operation, +24.2dBm IIP3, 12.5dB NF, –42dBm LO Leakage, Supply Voltage = 3.15V to 5V LT5525 0.8GHz to 2.5GHz Low Power Down Converting Mixer On-Chip Transformer for Single-Ended LO and RF Ports, +17.6dBm IIP3, Integrated LO Buffer LT5527 400MHz to 3.7GHz High Signal Level Downconverting Mixer 23.5dBm IIP3 at 1.9GHz, NF = 12.5dB, Single-Ended RF and LO Ports LT5528 2GHz High Linearity Direct Quadrature Modulator OIP3 = 21.8dBm, –159dBm/Hz Noise Floor, –66dBc Four Channel ACPR, 50Ω Single-End RF Output LTC5532 300MHz to 7GHz Precision RF Power Detector Precision VOUT Offset Control, Adjustable Gain and Offset Voltage LTC5534 50MHz to 3GHz Log-Linear RF Power Detector 60dB Dynamic Range, Superb Temperature Stability, Tiny 2mm × 2mm SC70 Package, Low Power Consumption 5522fa 16 Linear Technology Corporation LT 1105 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 2003
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