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Preliminary RF3320 CABLE REVERSE PATH PROGRAMMABLE GAIN AMPLIFIER 3 Typical Applications * Euro-DOCSIS/DOCSIS Cable Modems * CATV Set-Top Boxes * Telephony Over Cable * Home Networks * Automotive/Mobile Multimedia * Coaxial and Twisted Pair Line Driver 3 -A- The RF3320 is a variable gain amplifier for use in CATV reverse path (upstream) applications. It is DOCSIS-compliant for use in cable modems. The gain control covers a 58dB range and is serially programmable via three-wire digital bus for compatibility with standard baseband chipsets. Amplifier shutdown and transmit disable modes are software- and hardware-controlled. The device is placed into software-shutdown mode via the serial control bus. The device operates over the frequency band of 5MHz to 65MHz for use in current U.S. and European systems. The amplifier delivers up to 60dBmV at the output of the balun. Gain is controllable in accurate 1dB steps. The device is provided in a thermally enhanced, exposed die flag package. Optimum Technology Matching(R) Applied 3.90 + 0.10 0.25 + 0.05 0.05 + 0.05 Note 3 4.90 + 0.20 0.65 NOTES: 1. Shaded lead is pin 1. 2. Lead coplanarity - 0.10 with respect to datum "A". 3. Lead standoff is specified from the lowest point on the package underside. 6.00 + 0.20 1.40 + 0.10 EXPOSED DIE FLAG 8 MAX 0 MIN 3.302 0.60 + 0.15 0.24 0.20 2.286 Package Style: SSOP-16 EDF Slug uSi Bi-CMOS SHDNB TX EN NC VIN VINB VCC VCC RAMP 1 2 3 4 5 6 7 8 Si BJT GaAs HBT SiGe HBT GaAs MESFET Si CMOS Features * Single 5V Supply * Differential Input and Output * -30dB to +28dB Voltage Gain Range * 5MHz to 65MHz Operation * Sophisticated Power Management * DOCSIS 1.1 RF Compliant 16 Power Control GND NC NC VOUT VOUTB SDA CS SCLK 15 14 13 12 11 Gain Control and Serial Bus 10 9 Ordering Information RF3320 RF3320 PCBA Cable Reverse Path Programmable Gain Amplifier Fully Assembled Evaluation Board Functional Block Diagram RF Micro Devices, Inc. 7625 Thorndike Road Greensboro, NC 27409, USA Tel (336) 664 1233 Fax (336) 664 0454 http://www.rfmd.com Rev A10 010514 3-27 LINEAR CATV AMPLIFIERS Product Description RF3320 Absolute Maximum Ratings Parameter Supply Voltage Input RF Level Operating Ambient Temperature Storage Temperature Humidity Maximum Power Dissipation Maximum TJ Preliminary Rating -0.5 to +6.0 12 -40 to +85 -40 to +150 80 0.5 150 Unit VDC dBm C C % W C Caution! ESD sensitive device. RF Micro Devices believes the furnished information is correct and accurate at the time of this printing. However, RF Micro Devices reserves the right to make changes to its products without notice. RF Micro Devices does not assume responsibility for the use of the described product(s). 3 LINEAR CATV AMPLIFIERS Parameter Overall Specification Min. Typ. Max. Unit Condition VCC =4.75V to 5.25V, TXEN=SHDNB=1, VIN =30dBmV (rms) differential, output impedance=75 through a 2:1 transformer. Typical performance is at TA =+25C, VCC =5V. DC Specifications Supply Voltage Supply Current Maximum Gain Low Gain Transmit Disable Software-Shutdown Sleep Logic High Voltage Logic Low Voltage Logic Leakage Current 4.75 5.0 130 65 25 3 0.05 2 -1 0.8 1 5.25 160 105 35 5 V mA mA mA mA mA V V A Gain Control Word=58 Gain Control Word<35 TXEN=0 Bit 7 of gain control word FALSE SHDNB=0 AC Specifications Voltage Gain Maximum Minimum 3dB Bandwidth 1dB Compression Point Maximum Input Level Maximum Output Level ACPR 27 26 28 -30 100 66 34 60 -59 -47 -29 -28 dB dB dB dB MHz dBmV dBmV(rms) dBmV(rms) dBc 5MHz to 42MHz; Gain Control Word=58 42MHz to 65MHz; Gain Control Word=58 5MHz to 42MHz; Gain Control Word=0 42MHz to 65MHz; Gain Control Word=0 Intended operating range is 5MHz to 65MHz. Modulated. To meet distortion specifications. Modulated. Into 75 load at balun output, all distortion tones <-50dBc. VIN =34dBmV (rms); QPSK modulation; Symbol rate=160ksps (2 bits per symbol); 20-bit PRBS (pseudo-random bit stream); 0.25 alpha root cosine filter Tones at 40MHz and 40.2MHz, VOUT =+54dBmV/tone, maximum gain, OIP3 is therefore +84dBmV, IIP3 is 58dBmV. Output IM3 -58 -55 dBc Output Third Harmonic Distortion F=20MHz, VOUT =59dBmV F=65MHz, VOUT =59dBmV Output Second Harmonic Distortion F=20MHz, VOUT =59dBmV F=65MHz, VOUT =59dBmV -60 -55 -55 -50 dBc dBc Maximum Gain, CW Maximum Gain, CW -70 -70 -60 -60 dBc dBc Maximum Gain Maximum Gain 3-28 Rev A10 010514 Preliminary Parameter AC Specifications, cont'd Output Step Size Isolation in Transmit Disable Mode Output Noise Maximum Gain Minimum Gain Transmit Disabled TX EN Enable Time TX EN Transient Duration Output Switching Transients Output Impedance 2.4 0.8 -80 1.0 -95 1.1 dB dBc RF3320 Specification Min. Typ. Max. Unit Condition Maximum Gain, 20MHz -37 -55 -75 0.5 3.0 5 3 300 -30 -50 -70 1.0 255 10 5 345 S mVP-P mVP-P Input Impedance 75 28 C/W Time for gain to reach 99% of final value. See Note 1. See Note 1. Maximum Gain Minimum Gain Chip output impedance is nominally 300. Differential to single-ended output conversion to 75 is performed in a balun with a 2:1 turns ratio, corresponding to a 4:1 impedance ratio. Differential Thermal ThetaJC Note 1: The enable time is determined by the value of the capacitor on pin 8 (RAMP). A higher capacitor value will increase the enable time, but will reduce the transient voltage. Rev A10 010514 3-29 LINEAR CATV AMPLIFIERS dBmV/ 160kHz dBmV/ 160kHz dBmV/ 160kHz S -96dBc for a 59dBmV carrier in a 160kHz bandwidth. -64dBc for an 8dBmV carrier in a 160kHz bandwidth. TXEN =0 3 RF3320 Pin 1 2 3 4 5 Function SHDNB TX EN NC VIN VINB Description Chip shutdown pin. Forcing a logic low causes all circuits to switch off and gain settings to be lost. Signal path enable pin. Logic high turns on signal path. Logic low turns off signal path, but leaves serial bus active. Not connected. This pin should be grounded. Input pin. This should be externally AC-coupled to signal source. Complementary input pin. This should be externally coupled to signal source. For single-ended use, this pin should be AC-coupled to ground. Preliminary Interface Schematic See pin 5. VCC 3 LINEAR CATV AMPLIFIERS VIN 550 550 500 500 VINB 6 7 8 9 10 11 12 13 VCC VCC RAMP SCLK CS SDA VOUTB VOUT This pin is connected to the supply voltage. Same as pin 6. An external capacitor between this pin and ground controls turn-on time. Serial bus clock input. Serial bus enable. Serial bus data input. Open collector output. Connect to VCC via balun primary. Open collector output. Connect to VCC via balun primary. VOUT VOUTB See pin 13. 300 RE 14 15 16 PKG BASE NC NC GND GND Same as pin 3. Same as pin 3. Connect to ground. Die is mounted on a heat sink slug that should be connected to ground. Device grounds are internally bonded to the slug. Serial Bus Block Diagram D6 D5 D4 D3 D2 D1 D0 D Q D Q D Q D Q D Q D Q D Q CK CLR CK CLR CK CLR CK CLR CK CLR CK CLR CK CLR CS POR SDA D Q D Q D Q D Q D Q D Q D Q CK CLR CK CLR CK CLR CK CLR CK CLR CK CLR CK CLR SCLK 3-30 Rev A10 010514 Preliminary Table 1. Serial Interface Control Word Format RF3320 Mnemonic D6 D5 D4 D3 D2 D1 D0 Bit MSB 6 5 4 3 2 1 LSB 0 Description Sleep Mode (Software Shutdown) Gain Control, Bit MSB Gain Control, Bit 4 Gain Control, Bit 3 Gain Control, Bit 2 Gain Control, Bit 1 Gain Control, Bit LSB Serial Bus Timing Diagram TES TDATAH,TDATAL TDS TDH TWH TEH 3 TC CS SCLK SDA (Data) D0 D1 D2 D3 D4 D5 D6 Table 2. Timing Data Parameter SCLK Pulsewidth SCLK Period Setup Time, SDA versus S CLK Setup Time, CS versus S CLK Hold Time, SDA versus S CLK Hold Time, CS versus S CLK SCLK Pulsewidth, High SCLK Pulsewidth, Low Symbol TWH TC TDS TES TDH TEH TDATAH TDATAL Min 50 100 10 10 20 20 50 50 Typ Max Units ns ns ns ns ns ns ns ns Table 3. Programming State TX Enter Sleep Mode Exit Sleep Mode Enter Shutdown Exit Shutdown TX Enable TX Disable X X X X H L SHDND H H L H X X MSB6 L H* X H* X X H=High Voltage Logic L=Low Voltage Logic X=Don't Care *Gain Control Data Must be Re-Sent Rev A10 010514 3-31 LINEAR CATV AMPLIFIERS RF3320 Typical Application Schematic SHDNB TXEN 1 2 3 10 nF VIN 4 10 nF VINB 5 6 7 8 220 pF PACKAGE BASE Gain Control and Serial Bus Power Control Preliminary 16 15 14 13 12 11 10 9 100 pF 4:1 VOUT VCC2 3 LINEAR CATV AMPLIFIERS VCC1 SDA CS SCLK 3-32 Rev A10 010514 Preliminary Evaluation Board Schematic CS SDA SCLK J5-1 J3-1 J1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 R2 100 k 15 16 17 18 19 20 21 22 23 24 25 NC NC VCC NC NC GND GND GND GND GND GND GND GND J6 RF IN T1 1:1 R3 75 C3 1 nF J3 NC CS SDA SCLK SHDNB TXEN NC NC NC VCC NC 3 3 GND 1 2 3 4 5 R4 75 VCC1 C5 0.1 F C6 220 pF Notes: 1. 4-layer board. 2. Underside of package must solder to ground. 3. Place C5 and C6 as close to pin as possible. 4. C1 is tantalum, size code Y. 5. All other components are 0603 size. 6. Replace R5 with 0 resistor if 75 connector is used. C4 1 nF 6 7 8 PACKAGE BASE 3320400B Gain Control and Serial Bus Power Control RF3320 J2 J1-6 TXEN 1 2 3 J4 J1-5 SHDNB 1 2 VCC GND VCC1 L4 (Ferrite) 30 VCC2 VCC VCC L3 (Ferrite) 30 C2 1 nF + C1 10 F (10 V) L2 (Ferrite) 30 L1 (Ferrite) 30 JP1 1 2 VCC GND 1 2 3 J5 1 2 R1 100 k VCC 3 16 14 13 12 11 10 9 C9 100 pF C7 15 pF C8 15 pF T2 4:1 VCC2 R5 24 J7 RF OUT SDA CS SCLK PCB Layout Considerations The RF3320 Evaluation board can be used as a guide for the layout in your application. Care should be taken in laying out the RF3320 in other applications. The RF3320 will have similar results if the following guidelines are taken into consideration: * Make sure underside of package is soldered to a good ground on the PCB. * Keep input and output traces as short as possible. * Ensure a good ground plane by using multiple vias to the ground plane. * Use a low noise power supply along with decoupling capacitors. Rev A10 010514 3-33 LINEAR CATV AMPLIFIERS 15 RF3320 Evaluation Board Layout Board Size 2.5" x 2.5" Board Thickness 0.058", Board Material FR-4 Preliminary 3 LINEAR CATV AMPLIFIERS 3-34 Rev A10 010514 Preliminary Gain versus Gain Control Word at 5 MHz 28.0 145.0 140.0 18.0 135.0 130.0 8.0 125.0 RF3320 Current versus Gain Control Word Current (mA) Gain (dB) 120.0 115.0 110.0 -2.0 3 LINEAR CATV AMPLIFIERS -12.0 105.0 -22.0 100.0 95.0 -32.0 0.0 5.0 10.0 15.0 20.0 25.0 30.0 35.0 40.0 45.0 50.0 55.0 90.0 0.0 5.0 10.0 15.0 20.0 25.0 30.0 35.0 40.0 45.0 50.0 55.0 Gain Control Word Gain Control Word Gain versus Frequency 28.40 25 Gain Control Word = 58 15 Gain Control Word = 29 Gain Control Word = 0 27.40 5 27.90 Gain versus Supply Voltage (GCW = 58) Voltage Gain (dB) Gain (dB) 26.90 -5 -15 26.40 -25 25.90 5 MHz 42 MHz 65 MHz -35 5 25 45 65 85 105 125 145 165 185 205 225 245 25.40 4.70 4.75 4.80 4.85 4.90 4.95 5.00 5.05 5.10 5.15 5.20 5.25 5.30 Frequency (MHz) Voltage (V) Gain versus Supply Voltage (GCW = 29) 0.00 5 MHz -0.20 42 MHz 65 MHz -0.40 -28.20 -28.40 -28.60 -28.80 -29.00 -29.20 -29.40 -29.60 -1.20 -29.80 -1.40 4.70 4.75 4.80 4.85 4.90 4.95 5.00 5.05 5.10 5.15 5.20 5.25 5.30 -28.00 Gain versus Supply Voltage (GCW = 0) 5 MHz 42 MHz 65 MHz Gain (dB) -0.60 -0.80 -1.00 Gain (dB) Voltage (V) -30.00 4.70 4.75 4.80 4.85 4.90 4.95 5.00 5.05 5.10 5.15 5.20 5.25 5.30 Voltage (V) Rev A10 010514 3-35 RF3320 Gain versus Frequency at Gain Control Word = 58 28.5 Temp = 85C 28.0 27.5 27.0 26.5 26.0 25.5 25.0 24.5 24.0 5 55 105 155 205 255 Temp = 0C Temp = -40C -2.0 -1.0 0.0 Preliminary Gain versus Frequency at Gain Control Word = 25 Temp = 85C Temp = 0C Temp = -40C Voltage Gain (dB) Voltage Gain (dB) -3.0 -4.0 3 LINEAR CATV AMPLIFIERS -5.0 -6.0 -7.0 -8.0 5 55 105 155 205 255 Frequency (MHz) Frequency (MHz) Gain versus Frequency at Gain Control Word = 0 -26.0 -26.5 -27.0 -27.5 20.0 30.0 85C 0C -40C Gain versus Gain Control Word Voltage Gain (dB) -28.0 -28.5 -29.0 -29.5 -30.0 -30.5 -31.0 -31.5 5 55 105 155 205 255 Temp = 85C Temp = 0C Temp = -40C Voltage Gain (dB) 10.0 0.0 -10.0 -20.0 -30.0 0 10 20 30 40 50 Frequency (MHz) Gain Control Word Gain versus Supply Voltage at Gain Control Word = 58 28.2 0.0 Gain versus Supply Voltage at Gain Control Word = 29 5 MHz at 85C 65 MHz at 85C 42 MHz at 0C 5 MHz at -40C 65 MHz at -40C 42 MHz at 85C 5 MHz at 0C 65 MHz at 0C 42 MHz at -40C 28.0 -0.2 -0.4 Voltage Gain (dB) Voltage Gain (dB) 27.8 5 MHz at 85C 65 MHz at 85C 42 MHz at 0C 5 MHz at -40C 65 MHz at -40C 42 MHz at 85C 5 MHz at 0C 65 MHz at 0C 42 MHz at -40C -0.6 27.6 -0.8 27.4 -1.0 27.2 -1.2 27.0 4.7 4.8 4.9 5.0 5.1 5.2 5.3 -1.4 4.7 4.8 4.9 5.0 5.1 5.2 5.3 Supply Voltage (V) Supply Voltage (V) 3-36 Rev A10 010514 Preliminary Gain versus Supply Voltage at Gain Control Word = 0 5 MHz at 85C 65 MHz at 85C 42 MHz at 0C 5 MHz at -40C 65 MHz at -40C 42 MHz at 85C 5 MHz at 0C 65 MHz at 0C 42 MHz at -40C RF3320 68.0 -28.0 -28.2 -28.4 -28.6 -1 dB Compression Point (GCW = 58) Gain Control Word = 58 67.0 Trend 66.0 Power Out (dBmV) Voltage Gain (dB) -28.8 -29.0 -29.2 -29.4 -29.6 -29.8 -30.0 4.7 4.8 4.9 5.0 5.1 5.2 5.3 65.0 64.0 63.0 3 LINEAR CATV AMPLIFIERS 62.0 61.0 60.0 33.8 34.8 35.8 36.8 37.8 38.8 39.8 40.8 41.8 Supply Voltage (V) Power In (dBmV) 40.0 39.0 38.0 37.0 36.0 35.0 34.0 33.0 32.0 31.0 33.8 34.8 -1 dB Compression Point (GCW = 29) Gain Control Word = 29 Trend Second Harmonic versus Frequency and Output Level -50.0 30dBmV 57dBmV -55.0 60dBmv Second Harmonic (dBc) 35.8 36.8 37.8 38.8 39.8 40.8 41.8 Power Out (dBmV) -60.0 -65.0 -70.0 -75.0 0.0 10.0 20.0 30.0 40.0 50.0 60.0 70.0 Power In (dBmV) Frequency (MHz) Third Harmonic versus Frequency and Output Level -50.0 -55.0 Third Harmonic (dBc) -60.0 30dBmV -65.0 57dBmV 60dBmV -70.0 -75.0 0.0 10.0 20.0 30.0 40.0 50.0 60.0 70.0 Frequency (MHz) Rev A10 010514 3-37 RF3320 S11 Transmit Enable = 5V S CH1 PRm Cor 11 log MAG 10 dB/ REF 0 dB 1: -19.249 dB 4.960 000 MHz 2: -20.665 dB 42.085 MHz 3: -21.65 dB 64.855 MHz Preliminary S22 Transmit Enable = 5V S CH1 PRm Cor 22 log MAG 10 dB/ REF 0 dB 1: -25.52 dB 4.960 000 2: -25.226 dB 42.085 MHz 3: -22.568 dB 64.855 MHz 3 LINEAR CATV AMPLIFIERS 1 1 2 3 2 3 START 1.000 000 MHz STOP 100.000 000 MHz START 1.000 000 STOP 100.000 000 MHz S11 Transmit Enable = 0V CH1 S 11 S22 Transmit Enable = 0V S CH1 22 1: -19.335 dB 4.960 000 MHz 2: -20.627 dB 42.085 MHz 3: -21.815 dB 64.855 MHz PRm Cor log MAG 10 dB/ log MAG 10 dB/ PRm Cor 1: -25.612 dB 4.960 000 MHz 2: -25.871 dB 42.085 MHz 3: -22.989 dB 64.855 MHz 1 1 2 3 2 3 START 1.000 000 MHz STOP 100.000 000 MHz START 1.000 000 MHz STOP 100.000 000 MHz 3-38 Rev A10 010514 Preliminary ACPR at 65MHz RF3320 ACPR at 42MHz 3 LINEAR CATV AMPLIFIERS ACPR at 5MHz Power Up Settling Time Coming Out Of Shutdown Condition Power Up Settling Time Coming Out Of Shutdown Condition (Entire Pulse) Power Up Settling Time Coming Out Of Sleep Condition Rev A10 010514 3-39 RF3320 Evaluation Kit General Description The RF3320 PCBA is a fully assembled evaluation board of the RF3320 reverse path high output power programmable gain amplifier, useful for providing a demonstration of the RF3320's functionality. The RF3320 PCBA is a digitally controlled variable gain amplifier capable of driving a 75 source. The RF3320 is designed to send cable modem data with QPSK or QAM modulated format at frequencies between 5MHz and 65MHz. The gain is controlled by an 7-bit serial data word which adjusts the output gain from -30dB to +28dB. The kit includes a fully functional evaluation board along with a serial data cable and software. The cable connects directly to the parallel port of a standard PC. The software is used to control the serially programmable gain through a simple, easy to understand user interface. Input and output to the evaluation board is provided through 50 SMA connectors. The input and output of the evaluation board is matched to 50 and connected through a balun for single-ended operation. This allows easy connection to test equipment, but the evaluation board can easily be converted to a 75 input and output, or for differential input and output. The output circuit is matched using a 24 series resistor which is used to bring the load impedance up to 75 when using standard 50 test equipment. This will introduce a loss which must be accounted for in all measurements (see measurement section and evaluation board schematic for more detail). PCBA Details Input Circuit The input to the RF3320 is differential and the impedance is 75; However, for ease of testing, the evaluation board has been changed to single-ended and the impedance has been matched to 50. If a 75 input is required, simply replace the 50 SMA connector with a 75 F-style connector and remove R3 and R4. Output Circuit The output of the RF3320 is differential and the impedance is 300. In normal applications this is converted into a single-ended 75 output using a 2:1 (voltage ratio) transformer with a center-tap on the secondary which supplies power to the output stage. The evaluation board is configured for use with 50 test equipment. This has been achieved with a 24 resistor in series with the output to increase the load seen by the 3-40 Preliminary 3 LINEAR CATV AMPLIFIERS device to 75. This introduces a voltage loss of 3.5dB which must be accounted for in all measurements. Some spectrum analyzers have a setting to account for this method of 75 testing (e.g., on a Rhode & Schwartz spectrum analyzer the input can be set to '"75 RAZ" and the loss is accounted for automatically). A more accurate way of making this measurement is to use a 75 spectrum analyzer, or use a matching transformer or minimum loss pad. This ensures that the source impedance seen by the equipment is also 75. If a 75 output is required, simply replace the 50 SMA connector (J7) with a 75 Fstyle connector and replace R5 with a 0 jumper. The evaluation board is tested with a Coilcraft balun; however, additional baluns may be used as long as care is taken in modifying the decoupling capacitors around the balun. These capacitors can greatly affect the harmonic suppression. Other baluns may be used but should be tested for second and third order harmonic suppression. Transmit Enable The transmit enable can be set to "continuous on" by placing the TXEN jumper in the up position (up position when viewing the top of the evaluation board with the 25 pin connector closest to the viewer) and placing the associated GND/VCC jumper in the "VCC" position. The transmit enable can be set to "continuous off" by placing the GND/VCC jumper in the "GND" position. If a computer controlled signal is used (J1), place the TXEN jumper in the down position. GND VCC GND VCC GND VCC TX EN TX EN TX EN Continuous ON A Continuous OFF B Software Controlled C Figure 1. TX Enable Configuration Rev A10 010514 Preliminary Shutdown Enable Shutdown enable can be set to be "continuous on" (chip enabled) by placing the SHDN jumper in the up position and placing the associated GND/VCC jumper in the "VCC" position. Shutdown enable can be set to "continuous off" (chip disabled) by placing the associated GND/VCC jumper in the "GND" position. If a computer controlled signal is used (J1), place the SHDN jumper in the down position. VCC GND VCC GND VCC GND RF3320 Unzip the file using WinZip 7.0 or higher (http:// www.winzip.com). Unzip to a temporary directory and run RF3320.exe. The 7-bit Gain Control Word (GCW) in the data latch determines the gain setting in the RF3320. The gain control data (SDA) load sequence is initiated by a falling edge on CS. The SDA is serially loaded (LSB first) into the 7-bit shift register at each rising edge of the clock. While CS is low, the data latch holds the previous data word allowing the gain level to remain unchanged. After seven clock cycles the new data word is fully loaded and CS is switched high. This enables the data latch and the loaded register data is passed to the gain control block with the updated gain value. Also at this CS transition, the internal clock is disabled, thus inhibiting new serial input data. Software and Cable Figure 3 shows the cable configuration. Connect the cable into the LPT1 port of the computer running the software. Connect the other end of the cable to the 25pin connector of the evaluation board. Executing the software (RF3320.exe) will produce the screen shown in Figure 4. The user may set the gain of the evaluation board by sliding the gain control switch to the desired gain setting. Pressing the Preset Gain Value buttons automatically sets the gain of the unit to the value shown on the button. The Automatic Gain Adjustment when set to "Cycle" will automatically cycle through all of the gain steps (0-58) in seconds (at the rate set by the user). The user may place the unit in sleep, shutdown and transmit enable/disable modes by checking the corresponding box. The bit pattern being sent to the PCBA is shown at the bottom of the screen. See README_3320.txt file for proper pin/signal mapping for the 25 pin interface. 3 LINEAR CATV AMPLIFIERS SHDN SHDN SHDN Continuous OFF A Continuous ON B Software Controlled C Figure 2. SHDN Enable Configuration VCC Settings VCC1 should be set to 5.0VDC. Evaluation Board Setup Equipment Needed * Signal Generator * Spectrum Analyzer * Power Supply (5.0V@300mA) * RF3320 PCBA * Serial Cable (included with kit) * Standard PC * Three-Wire Bus Software Optional Equipment * Variable Low-Pass or Band-Pass Filters * Power Meter * Second Signal Generator with Modulation for ACPR and IP2, IP3 Testing * Arbitrary Wave Generator * Two-Channel Oscilloscope Software Setup To install the software, you need a computer with the following. * 133MHz Pentium processor * 16MB RAM * Hard Drive with 5MB free space * Free 25-pin LPT port * VGA Monitor The software may be downloaded from www.rfmd.com by following these steps. Select the "Product Support" tab; Select "Evaluation Board Information"; Select "RF3320". Rev A10 010514 3-41 RF3320 Preliminary RF3320 PCBA Cable 3 LINEAR CATV AMPLIFIERS 6 Ground 18 5 4 3 2 TX Enable Line SHUTDOWN Line CLK Line Data Line CS Line 25 Pin D-Connector (Back View) Figure 3. Cable Configuration Hardware Setup Gain and Harmonic Distortion Test Setup To test the gain of the RF3320 PCBA, connect a lowpass or band-pass filter to the output of the signal generator. Use a filter just above the frequency you want to test. The filter is used to attenuate any harmonics output by the signal generator. Connect the signal generator to the power meter and measure the power. Compare with modulation enabled and disabled to make sure the meter was measuring average rather than peak power. No more than 0.2dB difference in power should be observed. An offset on the signal generator may be needed to match the level shown on the power meter. The signal generator should then be connected directly to a spectrum analyzer. Make sure the output of the signal generator is the same as the input read by the spectrum analyzer. Adjust the offset of the spectrum analyzer until the signal out is the same as the signal in on the spectrum analyzer. Turn off the RF and modulation. Check positioning of the jumpers on the board. Refer to the PCBA section of this application note to verify proper positions. Connect the output of the signal generator to J6: RFIN of the PCB. Connect J7: RFOUT to the spectrum analyzer. Ensure that 3-42 Figure 4. On-Screen Display you are accounting correctly for the losses in the 75 to 50 conversion at the output of the device; there is an output voltage loss of 3.5dB for the evaluation board in its standard configuration (see output stage circuit description). Connect one end of the serial cable into the computer and the other end into J1 of the PCB. Connect +5.0VDC into V+ and ground into GND(JP1). Turn on the DC power and turn on RF from the signal generator. Set the GCW to 58 and make sure TXEnable is checked. The amplified signal should be displayed on the spectrum analyzer. The harmonics can also be viewed with this setup. As you change the GCW from 58 to 0 (in steps of one), there will be a 1dB change in the output of the PCB. ACPR Test Setup To test the ACPR of the RF3320 PCBA set modulation to: * QPSK * 2Bits/Sym * 160ksps * =0.25 * PRBS-20bit Data Rev A10 010514 Preliminary Set signal generator to: * 45MHz, * -13.0dBm output power, * 0dB offset. Connect 50MHz coaxial filter to output, then to output cable. Zero and calibrate the power meter. Connect signal generator to power meter and set offset on signal generator until power meter reads -13.0dBm. Make sure power meter reads the same (0.2dBm) with modulation enabled and disabled to verify power meter is measuring average power rather than peak power. Check positioning of the jumpers on the board. Refer to the PCBA section of this application note to verify proper positions. Connect the output of the signal generator to J6: RFIN of the PCB. Connect J7: RFOUT to the power meter. Connect one end of the serial cable to the computer and the other end into P1 of the PCB. Connect +5.0VDC to VCC and ground to GND. Turn on the DC power and turn on RF and modulation from the signal generator. Set the GCW to 58 and make sure TX Enable is checked. Measure and record channel power at RFOUT using the power meter (accounting for 75/50 conversion losses). Connect RFOUT to spectrum analyzer and adjust offset of the spectrum analyzer until the channel power displayed by the spectrum analyzer is equal to the channel power recorded in the previous step (channel bandwidth=200kHz). Now use the spectrum analyzer to measure relative ACP (this way the uncertainties in the spectrum analyzer power measurement are immaterial). The ACP is measured in 200kHz channel bandwidths at a 220kHz offset (i.e., from 20kHz to 220kHz outside the channel). As you increase the input power, you will notice a degradation of the ACP upper and lower bands. Datasheet performance is measured at an input level of 34dBmV. Transmit Turn-On and Turn-Off Transients Use an Arbitrary Waveform Generator set to a 3V square wave, 5% duty cycle, 120Hz as the input to the transmit enable. Set a signal generator to 10MHz, 13.0dbm output power, 0dB offset. Connect output of the signal generator to J6, RFIN of the PCB. Remove the TXEN jumper and connect the arbitrary wave generator square wave output to the center pin of the TXEN 3-pin header. Connect the output of the evaluation board to the oscilloscope (channel 1). Connect the TXEN signal from the arbitrary wave generator to channel 2 of the oscilloscope and trigger off of the rising edge. As the TXEN line is sent, the oscilloscope will trigger and capture the pulsed RFOUT signal. This Rev A10 010514 RF3320 will be displayed on the oscilloscope. Measure the amount of time between 90 percent of the TXEN turnon to where the output signal reaches 90 percent of full turn-on. This is defined as the transmit turn-on time. To measure the transient pulse, replace the signal generator input with a 50 terminator and repeat the steps above. Measure the size of the transient. This can be affected by the CRAMP capacitor (C6), and the output balun and capacitor values around the balun. Larger values of CRAMP will decrease the transient voltage and increase the TX enable time. PCB Layout Considerations The RF3320 Evaluation board can be used as a guide for the layout in your application. Care should be taken in laying out the RF3320 in other applications. The RF3320 will have similar results if the following guidelines are taken into consideration: * Make sure underside of package is soldered to a good ground on the PCB. * Move C2, C7, C8, and C9 as close to T1 as possible. * Keep input and output traces as short as possible. * Ensure a good ground plane by using multiple vias to the ground plane. * Use a low noise power supply along with decoupling capacitors. 3 LINEAR CATV AMPLIFIERS 3-43 RF3320 Special Handling Information for Shrunk Small Outline Package (SSOP1-EPP) Products These packages are considered JEDEC Level 5 for moisture sensitivity and require special handling to assure reliable performance. The exposed copper slug on the bottom of the package improves both thermal and electrical performance. Since the RFIC is mounted directly on the thermal slug, and the slug is soldered directly on the PCB, the thermal resistance to the PCB is minimized. Also, the RF ground for the amplifier is established through this copper slug as it is soldered to the ground plane on the PCB. This offers the least inductance ground path available. Care must be taken when soldering these packages to the PCB. They are currently considered JEDEC Level 5 for moisture sensitivity. Therefore the parts must be handled in a dry environment prior to soldering, as is specified in the JEDEC specification. Specifically, RFMD recommends the following procedure prior to assembly: 1. Dry-bake the parts at 125C for 24 hours minimum. Note: the shipping tubes cannot withstand 125C baking temperature. 2. Parts delivered on tape and reel are already drybaked and dry-packed. These may be stored for up to one year, but must be assembled within 48 hours after opening the bag. 3. Assemble the dry-baked parts within two days of removal from the oven. 4. During this two-day period, the parts must be stored in humidity less than 60 percent. IMPORTANT! If the two-day period is exceeded, then this procedure must be repeated prior to assembly. Preliminary 3 LINEAR CATV AMPLIFIERS 3-44 Rev A10 010514 |
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