Electricity: measuring and testing – Impedance – admittance or other quantities representative of... – Lumped type parameters
Reexamination Certificate
2002-02-27
2004-03-30
Le, N. (Department: 2858)
Electricity: measuring and testing
Impedance, admittance or other quantities representative of...
Lumped type parameters
C324S126000
Reexamination Certificate
active
06714026
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to systems and methods for measuring power characteristics of an electric circuit. More particularly, this invention relates to on-board systems and methods for measure power characteristics of a circuit or sub-circuit on a Printed Circuit Board, and for measuring temperature and thickness of the circuit or sub-circuit.
2. Description of the Related Art
Printed Circuit Boards (PCBs) are well known. PCBs are a convenient and effective way to manufacture and implement both analog and digital electronics, often referred to as integrated circuits. Today, integrated circuits on PCBs are used in a multitude of applications, such as in computers, networking equipment, electronic appliances, stereos, etc.
In general, a PCB is manufactured to design specifications and lays out the electronic circuits for the associated application, such as the wiring for an integrated circuit. Then, after the PCB has been manufactured, the elements and various components of the integrated circuit are mounted onto the PCB at touch points, such as by soldering, etc.
As integrated circuits have become more and more complex, their related power consumption and distribution becomes more demanding. Accordingly, accurate testing of an integrated circuit's power needs is essential to the production of quality integrated circuits, and in turn, electrical and electronic equipment.
Often, analytical tools such as component modeling tools or simulation tools (e.g., SPICE®, etc.) are used by design engineers to help predict power consumption and distribution across an integrated circuit. However, many factors make the accurate prediction of the characteristics of an integrated circuit unreliable. For example, it is common for a PCB to be manufactured to tolerances of up to ±10%. Similarly, component tolerances may vary. Thus, the modeling of an integrated circuit may be used for design purposes, but might not accurately predict the actual power consumption and power distribution characteristics of an integrated circuit on a PCB, which could change with the varying tolerances. Accordingly, electronics manufacturers still must rely on conventional, laboratory type testing of integrated circuits manufactured on PCBs.
The physical testing of a integrated circuit on a PCB is not without its problems. For example, it is a common practice to test an integrated circuit by “breaking up” or isolating sections of a circuit or sub-circuit on the PCB. In order to isolate a circuit or sub-circuit, a component (e.g., an inductor, etc.) is usually removed and a power source is then spliced in, such as by a wire. Then, various voltage and current measurements may be made using conventional meters (e.g., voltage and current meters, oscilloscopes, etc.). However, as electronic components become smaller, physically isolating circuits on a PCB and accurately attaching scopes and meters to the circuit becomes more cumbersome, and is often impossible.
Ideally, to perform such testing, a precision measurement of the current feeding a circuit is necessary, which can be achieved by providing a precision current source in series with the circuit, or by adding a precision resistor in series with a voltage source to a circuit. For example, referring to prior art
FIG. 1
, shown is a simple block diagram of a circuit
100
on a PCB. The circuit
100
has a load
102
and a voltage source
104
. The power plane or PCB has a trace resistance level which is represented by R
2
. A precision resistor R
1
is placed in series with the power plane (R
2
), and a precision current can be measured feeding load
102
, such as by using a current meter across the precision resistor R
1
. However, by placing a component in series with the load (circuit)
102
, the reliability of the circuit is directly related to the reliability of the precision resistor R
1
. Accordingly, the reliability of the entire circuit may be reduced.
Adding components in series with the circuit itself could affect the inductances of the circuit and accordingly, affect overall performance. Moreover, precision resistors also have the problem that they often cannot handle high current.
Furthermore, many circuits on a PCB are powered and connected via embedded circuits. In the example described above, the power plane is most likely embedded in the PCB, and therefore, certain characteristics of the power plane, such as thickness, will not be known. These characteristics may vary from PCB to PCB due to manufacturing tolerances. It may be important to know certain characteristics of the power plane or other embedded circuits for on-board testing of circuits or for measuring power of a circuit on a PCB.
However, since these circuits are embedded, conventional methods of measuring their thickness or other characteristics might not succeed. For example, conventional surface thickness measuring devices cannot be contacted with a power plane which is embedded in a PCB.
In view of the aforementioned problems, there is a need for new and improved systems and methods for measuring the power of a circuit on a PCB that is accurate and non-intrusive, and for measuring other characteristics of embedded circuits in a PCB. Such systems and methods should limit the number of additional components added to the circuit being tested, and should allow testers better access to circuits or less cumbersome methods to make measurements.
SUMMARY OF THE INVENTION
The present invention provides a system for measuring a thickness of a circuit component on a printed circuit board (PCB) The system includes a first circuit, a power plane, a power strip, a calibration strip, a temperature sensor, and a second circuit. The power plane is coupled to the first circuit. The power strip is for providing power to the power plane and is disposed in said PCB connected to the power plane. The power strip has at least two vias. The calibration strip has a predetermined width and is disposed in the PCB. The calibration strip has at least two vias for measuring a voltage drop. The temperature sensor is coupled to the calibration strip and configured to measuring a temperature of the calibration strip. The second circuit is coupled to the temperature sensor and configured to determine the thickness of the calibration strip based on at least the temperature of the calibration strip.
According to another embodiment of the present invention, provided is a system for measuring a thickness of circuit components on a printed circuit board (PCB). the system includes a first circuit, a power plane, a power strip, a calibration strip, a temperature regulator, and a second circuit. The power plane is coupled the first circuit. The power strip is for providing power to the power plane disposed in the PCB connected to the power plane. The power strip has at least two vias. The calibration strip has a predetermined width and is disposed in the PCB,. The calibration strip has at least two vias for measuring a voltage drop. The temperature regulator is coupled to the PCB and configured to maintain the PCB at a set temperature. The second circuit is configured to determine the thickness of the calibration strip based on at least the set temperature of the calibration strip.
According to another embodiment of the present invention, provided is a method for determining a thickness of a power strip of a circuit on a printed circuit board (PCB). The method includes the steps following steps: disposing a circuit onto a PCB.; embedding a power strip having a first predetermined length and width into the PCB between a first power supply and the circuit during a manufacturing process; disposing a calibration strip having a second predetermined length and width into the PCB during the manufacturing process; providing a second power supply to the calibration strip and grounding the power strip to form a current flow through the power strip; measuring a first voltage across the power strip; measuring a second voltage across the calibration strip; determining a temperatur
Broadcom Corporation
Le N.
Squire Sanders & Dempsey L.L.P.
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