This application relates to measurement of spurious tones.
Signals generated by phase-locked loops and other timing circuits can include undesirable spurious tones. Accurately identifying the existence of spurious tones in a testing environment can help ensure that the parts being supplied do not generate significant spurious tones at frequencies of interest. Accordingly, improved measurement techniques for spurious tones are desirable.
A first device is supplied with a first frequency control word identifying a first frequency corresponding to a spurious tone of interest to be measured in a first signal generated by a device under test. A phase-locked loop (PLL) of the first device generates a second signal based on the first signal. Presence of the spurious tone in the second signal is determined using a spur cancellation circuit in the first device.
In another embodiment a spur measurement system includes a first device having a spur cancellation circuit responsive to a frequency control word identifying a spurious tone of interest to be measured in a first signal received by the first device. The spur cancellation circuit is configured to cancel the spurious tone in a second signal in the first device, the second signal based on the first signal. A storage location in the first device stores information generated in the spur cancellation circuit and used to cancel the spurious tone. A first magnitude of the spurious tone in the second signal is determined according to the information and a second magnitude of the spurious tone in the first signal is determined by the first magnitude divided by gains associated with the first device.
In another embodiment a method includes supplying a first device with a frequency control word identifying a frequency corresponding to a spurious tone of interest to be measured in a first signal. The method further includes generating the first signal in a device under test and generating a second signal in a phase-locked loop of the first device, the second signal based in part on the first signal. Presence of the spurious tone in the first signal is determined based on a spur cancellation circuit in the first device canceling the spurious tone in the second signal. A first magnitude of the spurious tone is determined in the second signal and a second magnitude of the spurious tone in the first signal is determined based on the first magnitude divided by gains associated with the first device.
The present invention may be better understood, and its numerous objects, features, and advantages made apparent to those skilled in the art by referencing the accompanying drawings.
The use of the same reference symbols in different drawings indicates similar or identical items.
Embodiments described herein relate to a spur, or tone, cancellation system or circuit such as one incorporated in a high-performance fractional-N highly-digital phase-locked loop (PLL). One such PLL is described in U.S. Pat. No. 9,762,250, entitled “Cancellation of Spurious Tones Within A Phase-Locked Loop With A Time-To-Digital Converter”, filed Jul. 31, 2014, naming Michael H. Perrott as inventor, which application is incorporated herein by reference. The spurious tone cancellation system in one device can be used to detect spurious tones in other devices in a lab or production test environment.
The spur cancellation circuit receives a programmable frequency control word (FCW) 119 that identifies the spur of interest to be cancelled. In the spur cancellation circuit 101, sine and cosine terms 131 and 133 at the programmable frequency are correlated against a sense node, dsense, 121 inside the PLL. The resulting error signals drive a pair of accumulators, which set the weights on the sine and cosine signals, producing a spur cancellation signal, dinject 135. Negative feedback drives the amplitude and phase of the cancellation signal to be such that no spur appears (or the spur is significantly reduced) in the PLL output signal 107.
While the spur cancellation circuit shown in
For each spur frequency of interest, the spur cancellation circuit generates sine and cosine weights. If there is no spur at the frequency of interest, the sine and cosine weights reflect the lack of a spur present at the frequency of interest by being approximately 0. If there is a spur at the frequency of interest, the existence of the spur will be confirmed based on the magnitude of the spur on the internal PLL signal r supplied by TDC 115. The spur sine and cosine weights associated with each FCW may be stored in storage 311. The storage 311 may be in locations separate from the spur cancellation circuit 307 or storage such as registers, flip-flops, or latches within the spur cancellation circuit 307. The spur amplitudes can be computed conventionally by taking the sine and cosine weights kept in storage 311 and converting the sine and cosine weights to the corresponding magnitude and phase representation. The conversion to magnitude and phase may be accomplished using (x2+y2)1/2 and tan−1(y/x), where x is âi and y is âq. Other embodiments can calculate the spur magnitude and phase in different ways depending on the specific implementation of the spur cancellation circuit. The magnitude and phase calculation can be done either on the integrated circuit with the PLL 305, e.g., if a microcontroller is available on chip, or off chip by accessing the weights storage 311 through the input/output port 309 and computing the amplitude in the test apparatus 315. In an embodiment, the spur on the DUT clock signal 302 can be determined based on the spur magnitude (determined using the sine and cosine weights) on the internal PLL signal r divided by the gains of the phase detector 111 and TDC 115 in the PLL. The gains associated with phase detector 111 and TDC 115 can be measured empirically or through simulation.
Referring to
Referring to
Once the spurs of interest have been measured to determine if they exist in the output clock signal 302 of DUT 301, the presence or absence of a spur above a specified level acts as a test instrument readout. The presence or absence of a spur may be used, e.g., to screen or bin parts, or to aide in process control in manufacturing. In addition, embodiments may store results of the spur testing in the DUT itself in NVM 331. The information may include, e.g., the frequencies of the spurs tested and the results of the testing.
Thus, various aspects have been described relating to spur measurement. The description of the invention set forth herein is illustrative, and is not intended to limit the scope of the invention as set forth in the following claims. Other variations and modifications of the embodiments disclosed herein, may be made based on the description set forth herein, without departing from the scope of the invention as set forth in the following claims.
Number | Date | Country | |
---|---|---|---|
Parent | 16018598 | Jun 2018 | US |
Child | 17399981 | US |