TOA THS4130 - Manual

Running Title—Attribute Reference vi Figures 1–1 Schematic of the Populated Circuit on the EVM (Default Configuration) 1-3 . . . . . . . . . . . . . . 1–2 Schematic 1-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ....

1-1 Introduction and Description Introduction and Description The Texas Instruments THS4130 evaluation module (EVM) helps designersevaluate the performance of the THS4130 operational amplifier. Also, thisEVM is a good example of high-speed PCB design. This document details the Texas Instruments THS4...

THS4130 EVM Specifications 1-3 Introduction and Description 1.3 THS4130 EVM Specifications Supply voltage range, ± V CC 5 V to ± 15 V (see the device data sheet) . . . . Supply current, I CC (see the device data sheet) . . . . . . . . . . . . . . . . . . . . . . . . Output drive, I O, V CC = ± 15 (s...

THS4130 EVM Schematic 1-4 Introduction and Description 1.5 THS4130 EVM Schematic Figure 1–2. Schematic

Additional Sample Schematics 1-5 Introduction and Description 1.6 Additional Sample Schematics For verification of jumper locations and other bypass components, see thecomplete EVM schematic in Figure 1–2. Figure 1–3. Fully-Differential In/Fully-Differential Out, Without Transformer + – THS4130 – + ...

Additional Sample Schematics 1-6 Introduction and Description Figure 1–5. VICR Level Shifter + – THS4130 – + V CC 402 Ω 24.9 Ω 0 Ω V IN AC 0 Ω 0 Ω RX1 0 Ω R1b Rx0 374 Ω R3b R3a 374 Ω R6a C1 V OCM C4 C6 R4b R4a 0 Ω 0 Ω Rx4 Rx5 49.9 Ω 49.9 Ω R10 Rx6 50 Ω Source NOTE: Shifting the VICR within the speci...

2-1 Using the THS4130 EVM Using the THS4130 EVM It is recommended that the user perform the following exercises to learn theusage of the EVM. This practice helps the user learn about the variousterminals on the EVM and their function. In addition, it suggests thecomponents and equipment needed to op...

2-2 Using the THS4130 EVM 2.1 Required Equipment - One double-output dc power supply ( ± 5 V, 100 mA output minimum) - Two dc current meters with resolution to 1 mA and capable of themaximum current the dc power supply can supply. If available, set thecurrent limit on the dc power supply to 100 mA. ...

2-3 Using the THS4130 EVM 2.3 Input and Output Setup 1) Ensure that JU3, JU4, and JU1 are not installed (open circuit). 2) Set the function generator to generate a 1 MHz, ± 0.5 V (1 V PP ) sine wave with no dc offset. 3) Turn off the function generator before proceeding to the next step. 4) Using a ...

2-4 Using the THS4130 EVM 2.4 Testing the EVM Setup 1) Turn on the dc power supply. 2) Verify that both the +5 V (current meter 1) and the –5 V (current meter 2) currents are below 20 mA. Caution: Currents above 20 mA indicate a possible short or a wrong resistor valueon the PCB. Do not proceed unti...

Butterworth Filter 2-6 Using the THS4130 EVM Note: Transformers are used to change the single ended signals to differentialsignal or vice versa. On this EVM, they can be populated according to theapplication or the experiment. The V OCM pin of the device may be connected to the center-tap of the tra...

THS4130 EVM Bill of Materials 2-7 Using the THS4130 EVM Figure 2–5. Gain vs Phase Butterworth filter with multiple feedback frequency response. VIN = –1 dBmRL = 200 Ω Diff VCC = ± 15 0 –4 –10 0.1 1 Gain – dB 2 6 f – Frequency – MHz 10 10 500 100 –8 –2 4 8 Phase Gain 2.8 THS4130 EVM Bill of Materials...

3-1 General High-Speed Amplifier Design Considerations General High-Speed Amplifier Design Considerations The THS4130 EVM layout has been designed for use with high-speed signalsand can be used as an example when designing PCBs incorporating theTHS4130. Careful attention has been given to component ...