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Fast fT-Ic Measurement Using the Keysight B2900A Series of SMUs

Technical Overviews

Introduction

The cutoff frequency (fT) is an important parameter to understand the operating frequency range of a bipolar transistor. To measure fT, a DC bias must be applied to place the transistor at the correct operating point while simultaneously using a network analyzer to measure its frequency characteristics.

The Keysight Technologies, Inc. B2901/02/11/12A Precision Source/Measure Unit is a compact and cost-effective bench-top Source/Measure Unit (SMU) that supplies precise sourcing and measurement capability at a very reasonable price.

In addition, the B2900A Series of SMUs supports enhanced trigger functions that enable each step of a bias sweep it performs to be synchronized with a frequency sweep performed by a network analyzer. These capabilities allow you to evaluate and plot parameters such as fT versus Ic very quickly and efficiently.

For all of these reasons, the B2900A Series of SMUs is the ideal bias source to use with network analyzers for the evaluation of transistor DC and RF characteristics. This technical overview explains the key features of the B2900A Series of SMUs in detail and shows how it can help to determine the fT-Ic characteristics of bipolar transistors.

System Configuration

Figure 1 shows a system configuration to perform fT-Ic measurement using the B2902A or B2912A dual channel SMU in conjunction with a network analyzer (such as one from the Keysight ENA or PNA series).

The bipolar transistor is connected through a bias-T (either built-in to the network analyzer or external) to the RF ports of the network analyzer and to the DC output terminals of the B2900A Series of SMUs.

The DC bias voltage or current of the B2900A Series of SMUs is applied to the DUT through the bias-T.

A PC can control the B2900A Series of SMUs and the network analyzer using GPIB, Local Area Network (LAN) or USB communication protocols. In addition, the B2900A Series of SMUs and network analyzer’s external trigger inputs and outputs are connected to each other, and the trigger signals are used to improve overall system performance.

What is the B2900A Series of SMUs?

An SMU combines the capabilities of a current source, a voltage source, a current meter and a voltage meter along with the capability to switch easily between these various functions in a single instrument. This gives it the ability to evaluate the IV characteristics of devices easily across all four quadrants without any additional equipment.

The members of the B2900A Series of SMUs are single or dual channel SMU units that offer a wide range of IV measurement capability for a variety of two-terminal and three-terminal devices. They cover currents from 10 fA to 3 A (DC)/10.5 A (pulse) and voltages from 100 nV to 210 V.

In addition to their DC operation mode, the B2900A Series of SMUs also has the ability to perform pulsed measurements in order to prevent device self-heating from distorting the measurement results.

Figure 2 provides an overview of the B2900A Series of SMUs. The channels of the B2900A Series of SMUs support both 2-wire and 4-wire measurements. A 4-wire measurement uses one pair of leads to force current and the other pair of leads to monitor (sense) voltage.

This eliminates the voltage measurement error caused by residual cable resistance. The B2900A Series of SMUs also supports a remote-sensing function that keeps the voltage applied to the sense point the same as the programmed voltage.

Keysight offers the 11612V Kelvin bias-T network to support 4-wire measurement. Performing a 4-wire measurement using the B2900A Series of SMUs and the 11612V Kelvin bias-T network eliminates the voltage error caused by the residual bias-T resistance.

From this discussion it is clear that the B2900A Series of SMUs can be used to perform both IV measurements and to act as a precision bias source in conjunction with a network analyzer. Conveniently, the B2900A Series of SMUs also supports triggering functions that allow it to be easily synchronized with other measurement equipment (such as network analyzers).

Measuring fT-Ic Characteristics

The cutoff frequency (fT) can be calculated from the H21 parameter, and the H parameters can be calculated from the measured S parameters. Figure 3a shows an example of fT extraction using H parameters.

The absolute value of H21 at 1 GHz is calculated, and a line is drawn at this point with a –6 dB/octave slope. The fT is defined as the intercept of this line with the X-axis.

To find the maximum cutoff frequency fT_max, the base current (Ib) is swept while measuring the collector current (Ic). At each step of the Ib sweep, S-parameters are measured and used to calculate the cutoff frequency, fT.

Figure 3b shows an example of a measured fT-Ic curve. The maximum cutoff frequency, fT_max, can be determined from this curve. In this example, the fT_max is 14.9 GHz when the collector current is approximately 40 mA.

Handshaking the B2900A Series of SMUs and a Network Analyzer

The B2900A Series of SMUs has sophisticated triggering functions that enable it to perform complicated measurement sequences in synchronization with other instruments. For example, the start of each measurement step in a sweep can be initiated using an external trigger signal. This is opposed to using a single trigger signal to start the entire sweep measurement.

In addition, the B2900A Series of SMUs can output trigger signals at the beginning and end of various measurement events, such as signal transition and data acquisition.

After incrementing the bias, the B2900A Series of SMUs sends a trigger signal to the network analyzer to notify that it is ready for the frequency sweep. After receiving the trigger signal, the network analyzer initiates a frequency sweep to measure the S parameters.

After the network analyzer completes its data transfer, it sends a trigger signal to the B2900A Series of SMUs and it measures the collector current. This process continues until the last voltage step has been reached.

Using this trigger-controlled handshake scheme, the fT-Ic measurement speed is much faster than it would be if the B2900A Series of SMUs and network analyzer were controlled programmatically using one of the supported communication protocols.

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