UPC3218GV

NEC's GENERAL PURPOSE UPC3217GV 5 V AGC AMPLIFIER UPC3218GV FEATURES • ON-CHIP LOW DISTORTION AMPLIFIER: IIP3 = -4 dBm at minimuim gain • WIDE AGC DYNAMIC RANGE: GCR = 53 dB TYP • ON-CHIP VIDEO AMPLIFIER: VOUT = 1.25 VP-P at single-ended output • SUPPLY VOLTAGE: VCC = 5 V • PACKAGED IN 8 PIN SSOP SUITABLE FOR SURFACE MOUNTING VOLTAGE GAIN vs. AUTOMATIC GAIN CONTROL VOLTAGE* 60 TA = +25ºC VCC = 5V 50 f = 45 MHz Pin = -50 dBm 40 ZL = 250Ω 30 20 10 0 -10 Voltage Gain, GV (dB) UPC3217GV 0 1 2 3 4 5 Automatic Gain Control Voltage, VAGC* (V) 70 TA = +25ºC VCC = 5V 60 f = 45 MHz Pin = -60 dBm 50 ZL = 250Ω 40 30 20 10 0 DESCRIPTION Voltage Gain, GV (dB) NEC's UPC3217GV and UPC3218GV are Silicon Monolithic ICs designed for use as AGC amplifiers for digital CATV, cable modems and IP telephony systems. These ICs consist of a two stage gain control amplifier and a fixed video gain amplifier. The devices provide a differential input and differential output for noise performance, which eliminates shielding requirements. The package is 8-pin SSOP (Shrink Small Outline Package) suitable for surface mount. These ICs are manufactured using NEC's 10 GHz fT NESATΙΙ AL silicon bipolar process. This process uses silicon nitride passivation film. This material can protect chip surface from external pollution and prevent corrosion/migration. Thus, these ICs have excellent performance, uniformity and reliability. NEC's stringent quality assurance and test procedures ensure the highest reliability and performance. UPC3218GV 0 1 2 3 4 5 Automatic Gain Control Voltage, VAGC* (V) APPLICATIONS • • • Digital CATV Cable modem receivers IP Telephony Receivers ELECTRICAL CHARACTERISTICS (TA = 25°C, VCC = 5 V, ZS = 1 K Ω, ZL = 240 Ω, fIN = 45 MHz, Unless otherwise specified) PART NUMBER PACKAGE OUTLINE SYMBOLS PARAMETERS AND CONDITIONS DC Characteristics ICC Circuit Current (no input signal) RF Characterisitics BW Frequency Bandwidth, VAGC* = 4.5 V1 GMAX Maximum Gain , VAGC* = 4.5 V GMIN Minimum Gain, VAGC* = 0.5 V GCR Gain ConTrol Range, VAGC* = 0.5 to 4.5 V NFAGC Noise Figure, VAGC* = 4.5 V at MAX Gain VOUT Output Voltage, Single Ended Output Third Order Intermodulation Distortion, IM3 fIN1 = 44 MHz, fIN2 = 45 MHz, VIN = 30 dBmV per tone2 Note: 1. -3dB with respect to 10 MHz gain 2. VAGC is adjusted to establish VOUT = 1.25 VP-P per tone UNITS mA MHz dB dB dB dB VP-P dBc UPC3217GV S08 MIN 15 TYP 23 100 53 0 53 6.5 1.25 55 MAX 34 MIN 15 UPC3218GV S08 TYP 23 100 63 10 53 3.5 1.25 55 MAX 34 50 -4.5 46.5 56 3.5 8.0 60 4.5 46.5 66 13.5 4.5 California Eastern Laboratories * VAGC shown as applied in the evaluation cicuit (see page 5) through a resistive bridge (voltage divider). Actual voltage range on the pin of the IC is 0 to 3 V. UPC3217GV, UPC3218GV ABSOLUTE MAXIMUM RATINGS1 (TA = 25°C, unless otherwise specified) SYMBOLS VCC PD TOP1 TSTG PARAMETERS Supply Voltage Power Dissipation2, TA = 85˚C Operating Ambient Temp. Storage Temperature UNITS V mW °C °C RATINGS 6.0 433 -40 to +85 -50 to +150 RECOMMENDED OPERATING CONDITIONS SYMBOL VCC TA VAGC2 VIN PARAMETER Supply Voltage Operating Ambient Temp.1 Gain Control Voltage Range Video Input Signal Range UNITS MIN TYP MAX V °C V dBmV 4.5 -40 0 8 5.0 +25 – 5.5 +85 3.0 30 Notes: 1. Operation in excess of any one of these parameters may result in permanent damage. 2. Mounted on a 50 x 50 x 1.6 mm epoxy glass PWB, with copper patterning on both sides. Note: 1. VCC = 4.5 to 5.5 V 2. AGC range at pin 4 of the IC ORDERING INFORMATION PART NUMBER UPC3217GV-E1 UPC3218GV-E1 QUANTITY 1 kp/Reel 1 kp/Reel Note: Embossed tape 8 mm wide. Pin 1 indicates pull-out direction of tape. TYPICAL PERFORMANCE CURVES (TA = 25°C, UPC3217GV NOISE FIGURE vs. AUTOMATIC GAIN CONTROL VOLTAGE* 25 TA = +25ºC VCC = 5.0V f = 45 MHz ZL = 250Ω unless otherwise specified) UPC3218GV NOISE FIGURE vs. AUTOMATIC GAIN CONTROL VOLTAGE* 25 TA = +25ºC VCC = 5.0V f = 45 MHz ZL = 250Ω Noise Figure, NF (dB) 20 20 Noise Figure, NF (dB) 15 15 10 10 5 5 0 0 0 2.5 3 3.5 4 4.5 5 0 2.5 3 3.5 4 4.5 5 Automatic Gain Control Voltage, VAGC (V) NOISE FIGURE vs. FREQUENCY 10 9 TA = +25ºC VCC = 5.0V ZL = 250Ω VAGC = 4.5V Automatic Gain Control Voltage, VAGC (V) NOISE FIGURE vs. FREQUENCY 10 9 TA = +25ºC VCC = 5.0V ZL = 250Ω VAGC = 4.5V Noise Figure, NF (dB) 7 6 5 4 3 2 1 0 0 30 60 90 120 150 Noise Figure, NF (dB) 8 8 7 6 5 4 3 2 1 0 0 30 60 90 120 150 Frequency, f (MHz) Frequency, f (MHz) * VAGC shown as applied in the evaluation cicuit (see page 5) through a resistive bridge (voltage divider). Actual voltage range on the pin of the IC is 0 to 3 V. UPC3217GV, UPC3218GV TYPICAL PERFORMANCE CURVES (TA = 25°C, UPC3217GV CIRCUIT CURRENT vs. SUPPLY VOLTAGE 30 25 No Input Signal 30 25 unless otherwise specified) UPC3218GV CIRCUIT CURRENT vs. SUPPLY VOLTAGE No Input Signal Circuit Current, ICC (mA) 20 15 10 5 0 TA = +25ºC 5 6 Circuit Current, ICC (mA) 20 15 10 5 0 TA = +25ºC 5 6 0 1 2 3 4 0 1 2 3 4 Supply Voltage, VCC (V) Supply Voltage, VCC (V) VOLTAGE GAIN vs. FREQUENCY 60 TA = +25ºC VCC = 5V Pin = -50 dBm ZL = 250Ω VOLTAGE GAIN vs. FREQUENCY 70 60 VAGC*= 4.5 V TA = +25ºC VCC = 5V Pin = -60 dBm ZL = 250Ω Voltage Gain, GV (dB) 50 VAGC* = 4.5 V 40 30 20 10 0 VAGC* VAGC* Voltage Gain, GV (dB) 50 40 30 20 10 VAGC*= 0.5 V 0 VAGC*= 2.5 V = 2.5 V = 0.5 V -10 -20 1 10 100 1000 -10 1 10 100 1000 Frequency, f (MHz) Frequency, f (MHz) VOLTAGE GAIN vs. AUTOMATIC GAIN CONTROL VOLTAGE* 60 TA = +25ºC VCC = 5.0V 50 f = 45 MHz Pin = -50 dBm 40 ZL = 250Ω 30 20 10 0 -10 0 VOLTAGE GAIN vs. AUTOMATIC GAIN CONTROL VOLTAGE* 70 TA = +25ºC VCC = 5.0V 60 f = 45 MHz Pin = -60 dBm 50 ZL = 250Ω 40 30 20 10 0 Voltage Gain, GV (dB) 1 2 3 4 5 Voltage Gain, GV (dB) 0 1 2 3 4 5 Automatic Gain Control Voltage, VAGC* (V) * VAGC shown as applied in the evaluation cicuit (see page 5) through a resistive bridge (voltage divider). Actual voltage range on the pin of the IC is 0 to 3 V. Automatic Gain Control Voltage, VAGC* (V) UPC3217GV, UPC3218GV TYPICAL PERFORMANCE CURVES, cont. UPC3217GV 3RD ORDER INTERMODULATION DISTORTION (TA = 25°C, unless otherwise specified) UPC3218GV 3RD ORDER INTERMODULATION DISTORTION Output Power Pout/tone, (50Ω/250Ω) (dBm) Output Power Pout/tone, (50Ω/250Ω) (dBm) 20 Vcc = 5.0 V f1 = 44 MHz f2 = 45 MHz 0 ZL = 250 Ω VAGC* = 0.5 V VAGC* = 2.5 V VAGC* = 4.5 V 20 Vcc = 5.0 V f1 = 44 MHz f2 = 45 MHz 0 ZL = 250 Ω VAGC* = 0.5 V VAGC* = 2.5 V VAGC* = 4.5 V -20 -20 -40 -40 -60 -60 -80 -60 -50 -40 -30 -20 -10 0 -80 -70 -60 -50 -40 -30 -20 -10 Input Power Pin/tone, VCC (V) Input Power Pin/tone, VCC (V) Output Power Pout/tone, (50Ω/250Ω) (dBm)NOTE Output Power Pout/tone, (50Ω/250Ω) (dBm)NOTE OUTPUT POWER vs. INPUT POWER 10 0 -10 -20 -30 VAGC* = 2.5 V -40 -50 -60 -70 -60 -50 VAGC* = 0.5 V -40 -30 -20 TA = +25ºC VCC = 5.0V f = 45 MHz ZL = 250Ω -10 0 10 VAGC* = 4.5 V OUTPUT POWER vs. INPUT POWER 10 0 -10 -20 -30 VAGC* = 2.5 V -40 -50 -60 -70 -70 -60 VAGC* = 0.5 V -50 -40 -30 TA = +25ºC VCC = 5.0V f = 45 MHz ZL = 250Ω -20 -10 0 VAGC* = 4.5 V Input Power Pin/tone, VCC (V) Input Power Pin/tone, VCC (V) NOTE: Measurement value with spectrum analyzer. * VAGC shown as applied in the evaluation cicuit (see page 5) through a resistive bridge (voltage divider). Actual voltage range on the pin of the IC is 0 to 3 V. UPC3217GV, UPC3218GV TYPICAL SCATTERING PARAMETERS S11-FREQUENCY S22-FREQUENCY 2 1 2 1 Start Stop 1 MHz 500 MHz Marker 1: UPC3217GV 1.339k-j 1.556 kΩ Marker 2: UPC3218GV 1.024k-j 1.124 kΩ Start Stop 1 MHz 500 MHz Marker 1: UPC3217GV 9.511 + j 3.869 Ω Marker 2: UPC3218GV 9.493 + j 4.317 Ω SYSTEM APPLICATION EXAMPLE VCC (5 V) 1µf Signal Generator 50Ω SAW Filter RL = 1000Ω 1µf 10kΩ VAGC (0-5 V) 13kΩ 4 AGC Cont. 5 Spectrum Analyzer (50Ω) 1 1 µf 2 3 7 RL 6 1µf 500Ω 8 1µf Differential Probe (10:1) 1MΩ // 7pF 1µf EVALUATION BOARD SCHEMATIC AND TEST + - C5 1µf C6 1nf VCC DC_Bias UPC3219GV GND2 C3 1µf AGC_IN2 AGC_OUT2 C4 1 µf VAGC AGC_Control GND1 240Ω R3 190Ω Spectrum Analyzer 1:16 Signal Generator R1 0 R2 C1 1µf C2 1µf AGC_IN1 AGC_OUT1 R5 0 + - 0 10K C7 13k 1µf C8 1nf UPC3217GV, UPC3218GV PIN EXPLANATIONS Pin No. Name (UPC3217GV, UPC3218GV common) Pin Voltage (v)1 Description Internal Equivalent Circuit Applied Voltage (v) 4.5 to 5.5 1 VCC Power supply pin. This pin should be externally equipped with bypass capacitor to minimize ground impedance. 1.45 Signal input pins of AGC amplifier. AGC Control 2 INPUT1 1 3 INPUT2 1.45 2 5 3 4 VAGC 0 to 3.0 VCC Gain control pin. This pin's bias govern the AGC output level. Minimuim Gain at VAGC = 0.5 V Maximum Gain at VAGC = 4.5 V Recommended to use a 0 to 5 V AGC range for the system and divide this voltage through a resistive bridge (see evaluation board). This helps make the AGC slope less steep. Ground pin. This pin should be connected to system ground with minimum inductance. Ground pattern on the board should be formed as wide as possible. 2.2 Signal output pins of video amplifier 1 4 AGC Amp 5 5 GND 2 0 6 OUTPUT2 1 7 7 OUTPUT1 2.2 6 8 8 GND 1 0 Ground pin. This pin should be connected to system ground with minimum inductance. Ground pattern on the board should be formed as wide as possible. All ground pins must be connected together with wide ground pattern to decrease impedance difference. Note: 1. PIN is measured at VCC = 5 V UPC3217GV, UPC3218GV OUTLINE DIMENSIONS (Units in mm) PACKAGE OUTLINE S08 8 7 6 5 UPC3217/18GV 3 -3ß +7ß EVALUATION BOARD 3217: UPC3217GV 3218: UPC3218GV 321X N Detail of Lead End 1 2 3 3.0 MAX 4 +0.10 0.15 -0.05 4.94±0.2 3.2±0.1 0.87±0.2 1.5±0.1 1.8 MAX 0.1±0.1 0.65 +0.10 0.3 -0.05 0.5±0.2 0.575 MAX 0.15 All dimensions are typical unless specified otherwise. EVALUATION BOARD ASSEMBLY INTERNAL BLOCK DIAGRAM 1 2 3 4 AGC at Cont. 5 Vcc P1 P2 J1 uPC3217/18GV 6 Agc_IN1 J3 Out1 7 8 R1 T1 R5 C1 R2 C2 R6 C7 C8 J2 C5 C6 R3 C3 C4 R4 T1 R7 R6 R4 R3 R1,R2,R5 C6, C8 U1 Transformer4:1 Coilcraft 0603 10K OHM RES ROHM 0603 13K OHM RES ROHM Agc_IN2 Vagc R7 J4 0603 240 OHM RES ROHM 0603 191 OHM RES ROHM 0603 0 OHM RES ROHM 0603 1000pF CAP ROHM IC NEC, UPC3217/18GV IC NEC 101010 Out2 C1–C5, C7 0805 1uF CAP ROHM Life Support Applications These NEC products are not intended for use in life support devices, appliances, or systems where the malfunction of these products can reasonably be expected to result in personal injury. The customers of CEL using or selling these products for use in such applications do so at their own risk and agree to fully indemnify CEL for all damages resulting from such improper use or sale. 05/03/2004