Solid state USB RF SP4T Switch Matrix USB-2SP4T-63H 50 10 to 6000 MHz The Big Deal Very high isolation, 85 dB typ High speed switch transition, 5 s typ High power handling, +30 dBm max Software Package Daisy-chain control of up to 35 modules Case Style: QM2605 Model No. Description Qty. Typical Applications Switch Matrix 1 USB-2SP4T-63H Cellular handset / BTS testing Included Accessories High volume production testing / ATE MUSB-CBL-3+ 2.6 ft USB cable 1 Design verification testing RF signal routing / switch matrices RoHS Compliant See our web site for RoHS Compliance methodologies and qualifications Product Overview Mini-Circuits USB-2SP4T-63H is a low cost, USB controlled, solid state matrix, containing two independent SP4T RF switches. Each fast switching, absorptive switch operates from 10 MHz to 6000 MHz with 5 s typical switch transition speed. High linearity (+50 dBm typ IP3), and high isolation (85 dB typical) allow the model to be used for a wide variety of RF applications. Full software support is provided for USB control, including our user-friendly GUI application for Windows and a full API with programming instructions for Windows and Linux environments (both 32-bit and 64-bit systems). The latest version of the full software package can be downloaded from USB-2SP4T-63H USB RF SP4T Switch Matrix Electrical Specifications 0 to +50C Parameter Port Conditions Min. Typ. Max. Units Operating Frequency 10 6000 MHz 10 to 700 MHz 2.1 3.5 700 to 2500 MHz 2.5 4.0 Insertion Loss COM to any active port dB 2500 to 5000 MHz 2.9 4.3 5000 to 6000 MHz 3.3 4.7 10 to 700 MHz 78 105 700 to 2500 MHz 74 105 Between ports 1 to 4 of a given switch 2500 to 5000 MHz 63 90 5000 to 6000 MHz 58 80 10 to 700 MHz 77 105 700 to 2500 MHz 73 100 COM to any terminated port of a given switch 2500 to 5000 MHz 60 79 5000 to 6000 MHz 58 70 Isolation 10 to 700 MHz 77 105 dB COM to port 1, 2, or 4 of a given 700 to 2500 MHz 73 100 switch 1 2500 to 5000 MHz 60 79 (Disconnected state) 5000 to 6000 MHz 58 70 10 to 700 MHz 55 70 700 to 2500 MHz 37 48 COM to port 3 of a given switch 1 (Disconnected state) 2500 to 5000 MHz 30 39 5000 to 6000 MHz 28 36 Crosstalk between switches 10 to 6000 MHz 85 100 10 to 700 MHz 1.25 700 to 2500 MHz 1.25 COM port at all active states 2500 to 5000 MHz 1.45 5000 to 6000 MHz 1.40 10 to 700 MHz 1.25 700 to 2500 MHz 1.25 VSWR Any port connected to COM :1 2500 to 5000 MHz 1.25 5000 to 6000 MHz 1.30 10 to 700 MHz 1.20 700 to 2500 MHz 1.20 Any terminated port 2500 to 5000 MHz 1.25 5000 to 6000 MHz 1.40 Power Input COM to any active port 100 to 6000 MHz 33 dBm 1 dB Compression 2 IP3 COM to any active port 100 to 6000 MHz 50 dBm 3 Transition Time 5 8 s 4 Minimum dwell time High Speed Mode 15 s 5 Switching Time (USB) 2 ms Supply voltage (Vcc) 4.75 5 5.25 V DC 6 Supply Current (Icc) USB port 55 85 mA 7 Current Pass-through 500 Any active port to COM port Hot Switching +23 Any terminated port +23 Operating RF Input dBm Max power at through path derates linearly from Power 10 to 50 MHz +30 dBm 50 MHz to +23 dBm 10 MHz Through path 50 to 6000 MHz +30 1 In disconnected state COM port is reflective and ports 1-4 are absorptive, isolation COM to 1,2,4 is significantly better than COM to 3. See block diagram on page 3 for details. 2 IP3 is tested with 1 MHz span between signals, +5 dBm per tone. 3 Transition time spec represents the time that the RF signal paths are interrupted during switching and thus is specified without communication delays. 4 Minimum dwell time is the shortest time that can be achieved between 2 switch transitions when programming an automated switch sequence. 5 Switching time(USB) is the time from issuing a single software command via USB to the switch state changing. The most significant factor is the host PC, influenced by CPU load and USB protocol. The time shown is an estimate for a medium CPU load and USB 2.0 connection. 6 Current consumption specified for a single unit without any slave modules. 7 Pass through current is the maximum current handling of a unit with slave modules attached. If controlling a large number of slave modules additional power supplies should be included to ensure this limit is not exceeded. See page 4 for details. Mini-Circuits Page 2 of 9 www.minicircuits.com P.O. Box 350166, Brooklyn, NY 11235-0003 (718) 934-4500 sales minicircuits.com