WangYang1,2,*
ZhangYi2,3,*
GuoYufeng2
-
(Nanjing Vocational University of Industry Technology, Nanjing, 210023, China)
-
(National and Local Joint Engineering Laboratory of RF and Micro-assembly Technology,
University of Posts and Telecommunications, Nanjing, 210023, China)
-
(State Key Laboratory of Millimeter Waves, Southeast University, Nanjing, 210096, China)
Copyright © The Institute of Electronics and Information Engineers(IEIE)
Index Terms
Integrated circuit, frequency divider, broadband, programmable, SiGe
I. INTRODUCTION
With the gradual increase in the operating frequency of the communication systems,
the requirements for the operating frequency of the phase-locked loop (PLL) circuit
are also gradually increased. The frequency divider is an important part of the PLL
circuit, by which the overall performance of the PLL is directly determined. In general,
the frequency divider is required to cover the widest possible frequency band, the
largest possible frequency divider ratio, and the excellent input sensitivity so as
to maximize its application range. Therefore, investigation on the high frequency
broadband programmable frequency divider is a hotspot in this field [1-5].
Based on the scalable multi-mode frequency divider structure, this paper designs a
high-frequency broadband programmable frequency divider of 1-511 division ratio, with
the duty cycle being close to 50%. In modern communication systems and instruments,
frequency dividers with a wide range of continuously programmable frequency divisions
are required in both local oscillator sources and PLL sources. In this sense, the
present work is suitable for applications in these fields.
II. ARCHITECTURE DESIGN
The programmable frequency divider with a wide division ratio range usually adopts
a 2/3 frequency divider cascade structure. This structure has the advantages of high
reusability and easy expansion, but it needs to be optimized so as for the requirements
of any frequency division ratio.
1. Traditional 2/3 Divider Cascade Structure
The realization of programmable continuous frequency division based on the 2/3 divider
cascade structure [6,7], is shown in Fig. 1.
The principle of the basic unit circuit 2/3 frequency divider is that when Mod$_{in}$
is low, the circuit realizes 2 division; when Mod$_{in}$ is high, the frequency division
ratio realized is related to the control P$_{i}$: when P$_{i}$=0, it realizes 2 division;
when P$_{i}$=1, it realizes 3 division. Therefore, the actual output frequency $f_{i}$
of the ith 2/3 divider unit circuit is:
where $f_{i-1}$ is the input frequency and $f_{0}=f_{in}$.
The total frequency division ratio of multi-mode frequency divider cascaded by n-stage
2/3 frequency divider units is:
It can be deduced from Eq. (2) that the maximum and minimum frequency division ratios achieved by this structure
are 2$^{n}$$^{+1}$-1 and 2$^{n}$, respectively. In addition, the ratio of the maximum
frequency division to the minimum frequency division is approximately 2. Consequently,
the frequency division ratio range is limited. Therefore, in order to achieve the
frequency division ratio below 2$^{n}$, the above architecture needs to be optimized.
2. Multi-mode Frequency Divider with Expandable Frequency Division Ratio
On the basis of the circuit structure of Fig. 1, this article incorporates the corresponding logic operation to realize a multi-mode
frequency divider with an arbitrarily expandable frequency division ratio, thereby
achieving a continuous programmable frequency division ratio range from 1 to 511 ultimately.
The specific structure is shown in Fig. 2. Compared with the traditional structure shown in Fig. 1, the proposed structure can achieve a significantly wider frequency division ratio.
It can start with a continuous integer frequency division ratio starting from 1, and
the maximum frequency division ratio can be expanded arbitrarily with the extension
of the circuit, thereby showing better flexibility and versatility.
The structure consists of the selective trigger module, the frequency division link,
and the input logic module, as shown in the upper, middle, and bottom parts of Fig. 2, respectively. The selective trigger module makes the duty cycle of the output waveform
close to 50% through proper logic operation and trigger control. In contrast, the
traditional topology would lead to the obvious duty cycle imbalance of the output
waveform. The frequency division link is the core part of the whole circuit, completing
the operations of high-speed frequency division and pulse swallowing.
By designing appropriate logic operations, the frequency division link can break through
the lower limit of conventional frequency division ratio and completely cover 1 to
511.
The proposed structure adds a control terminal P$_{n}$ and an additional combinational
logic circuit on the traditional 2/3 frequency divider cascade structure to expand
the frequency division ratio. Assuming that the mod input of the n'th 2/3 frequency
divider unit is set as valid, and all the units on the right side are made invalid
through the combinational logic and control terminal, the effective number of cascaded
2/3 frequency dividing units is n'. Therefore, the lowest frequency division ratio
of the programmable frequency divider is 2$^{n}$$^{\mathrm{'}}$. Herein, n' is called
the effective length of the programmable frequency divider. If the above-mentioned
control logic makes all the mod signals valid, the highest divider ratio becomes 2$^{n}$$^{+1}$-1.
It can be found that the maximum and minimum frequency division ratios are related
to n and n', respectively. The frequency division ratio of the above circuit can be
expanded easily by choosing the values of n and n' appropriately. The state of each
2/3 frequency dividing unit can be controlled by the two reset signals r1 and s1,
which are obtained from the combinational logic of the external mode control terminals
P$_{0}$~P$_{n}$.
The above circuit optimization is easy to be implemented by adding simple combinational
logic only. Meanwhile, the advantages of the traditional 2/3 frequency divider such
as simple structure, low parasitic, and reusability are retained.
Furthermore, the above circuit also includes a module that can adjust the traditional
imbalanced duty cycle of output signal to be approximately 50% through inner clock
triggering and reshaping, as described in the section below.
Fig. 1. Programmable frequency divider circuit based on 2/3 frequency divider stage.
III. CIRCUIT DESIGN
It can be seen from Fig. 2 that the crucial parts of the structure are the 2/3 dual-mode frequency divider unit
and the implementation of pulse swallow [7-9]. Fig. 3 shows the block diagram of the optimized 2/3 dual-mode frequency divider unit. It
includes D flip-flops and two logic gates. The built-in reset signal can control the
2/3 divider cell to work in the reset state and the normal state. Compared with the
traditional three logic gates [7-9], this reset control can not only save a logic gate but more importantly, can effectively
reduce the loop delay time. This is very effective for increasing the maximum operating
frequency of the divider unit. Through a combinational logic cell, the external control
signal P$_{n}$ decodes the appropriate reset signals r1 and s1. These reset signals
and the mode signal Mod$_{in}$ from the pre-stage determine whether the current stage
circuit implements division by 2 or division by 3.
When the programmable frequency divider is working, if the bits from P$_{i}$ to P$_{n}$
are all 0, then each frequency division unit corresponding to P$_{i}$ to P$_{n}$ does
not work. Therefore, the s1_i signal corresponding to the P$_{i}$ control bit is high,
the main frequency division branch of this stage is set to logic high, and the corresponding
2/3 frequency division unit has no output. At the same time, the s1_i signal sets
the corresponding latch output of Mod$_{out}$ to logic high. Therefore, the s1_i signal
is the temperature code. If the P$_{i}$ control bit is low, the corresponding pulse
swallow latch is reset to logic low. Therefore, the implementation of the input logic
in Fig. 2 can be simplified and is shown in Fig. 4.
In order to achieve the highest possible operating frequency, the D flip-flops of
the first-stage 2/3 divider unit utilize the ECL structure. At the same time, in order
to minimize the delay of the feedback loop of the prescaler in Fig. 3, the combinational logic is merged into the D flip-flop [10,11], as shown in Fig. 5. The proposed structure incorporates the necessary logical operations for dual mode
prescaler and thus has lower power consumption.
The structure in Fig. 5 can realize the AND operation of input A and input B, which is implemented in the
read-in cycle of the flip-flop. This can eliminate the individual AND gate delay time
and effectively improve the maximum operating speed of the frequency divider. Similarly,
the overall delay time of the logic controller can also be effectively shortened to
achieve the best timing matching with the prescaler module. This can ensure the correctness
of the high-frequency swallowing pulse. The reset branch can also be merged into the
flip-flop without increasing circuit delay. In contrast, if the reset operation is
realized by using a conventional method similar to the A/B control signal, an additional
layer of devices is required, which is very unfavorable for low-voltage applications.
Therefore, only parallel devices are used to achieve the reset. Because the transistors
of the clk signal and the rst signal are in the same layer in topology, it is necessary
to specially control the high and low level values of the rst signal, which are wider
than those of the clk signal, so as to ensure that tail current can flow correctly
between Q5/Q6 and Q9 devices. If the difference between the voltage of the rst signal
and the clk signal is small, the current would not switch thoroughly, which will affect
the correct output voltage.
For the most crucial D flip-flop in the first-stage 2/3 frequency divider, its operating
point should be optimized to assure its operating speed greater than 16 GHz. The Q5/Q6
in Fig. 5 are the most important clock switching devices. It is required to adjust them to
the proper operating point with high cutoff frequency to meet the speed requirement.
At the same time, the load resistance should not be too large, and the signal swing
of 100 mV~150 mV is sufficient, which can reduce the circuit delay and power consumption.
When the previous two-stage 2/3 frequency divider works reliably, the operating frequency
of the latter 2/3 frequency divider has been reduced to less than 5 GHz. Therefore,
the subsequent D flip-flops can use the CML structure to reduce power consumption.
Even, the frequency divider in the last three stages can be realized by using a CMOS
circuit structure to further reduce power consumption. In order to maintain the low
phase noise characteristics of frequency divider circuits, all frequency dividers
in the frequency divider link adopt differential topology and are implemented by triode
devices. The first 2/3 frequency divider unit has a power consumption of 17 mW, and
the final stage has a power consumption of 2.6 mW.
Finally, using the pre-divided output clock as a trigger clock can effectively improve
the duty cycle of the inner divided signal. The principle is shown in Fig. 6. Herein, A is the output frequency division signal of the 2/3 frequency division
unit, B is the input clock signal of the same 2/3 frequency division unit, and C is
the output signal that uses the rising edge of B to re-trigger the frequency division
signal. It can be seen from the figure that the duty cycle adjustment can be well
realized by using the duty cycle change of the clock link itself.
Fig. 7 shows the simulation results of the frequency divider in divide-by-8 mode working
at a clock frequency of 16 GHz. The top, middle, and bottom subfigures are the input
clock clkin with an amplitude of 400 mVpp; the first stage 2/3 divider output signal
clka with an amplitude of 150 mVpp, and the final divide-by-8 output signal clkout
with an amplitude of 1.15 Vpp, respectively. It is seen from the figure that the first
stage 2/3 division signal, which is the most critical, has a swing of around 150 mVpp,
indicating that a faster response time and a reliable transmission of high-frequency
logic signals can be achieved.
Fig. 2. Multi-mode frequency divider circuit with expandable frequency division ratio.
Fig. 3. Block diagram of the 2/3 divider.
Fig. 4. Input control logic.
Fig. 5. Flip-flop merged logic gate: (a) Schematic; (b) Signal level.
Fig. 6. Output duty cycle adjustment.
Fig. 7. Simulation results for 16 GHz input.
IV. MEASUREMENT RESULTS
The chip is implemented in 0.18 ${\mu}$m SiGe BiCMOS process, the frequency divider
link is implemented by SiGe HBT device, and the logic control part is implemented
by CMOS device. The core area of the chip is 450 ${\mu}$m${\times}$350 ${\mu}$m. The
entire chip photo is shown in Fig. 8.
The divider is measured with 0 V/-3.3 V power for the testing convenience. Fig. 9 shows the output waveform of divide-by-8 and divide-by-511 with the 16 GHz clock
frequency. It can be seen from the figure that the output amplitude is greater than
1 Vpp with a 50 Ohm load, and the duty cycle of the output waveform does not show
obvious declination in various modes.
The input sensitivity in the mode of divide-by-8 is shown in Fig. 10. In this mode, the circuit can operate correctly with the input power of -20 dBm~+20
dBm. The red dot in Fig. 10 represents the upper limit of the input power for the chip during operation. Exceeding
this limit, the internal frequency division link does not work due to excessive signal
power, resulting in functional failure. The black dot in the figure represents the
lower limit of input power. If the input power is lower than this, the chip cannot
process properly and consequently cannot function properly. The chip can operate normally
and reliably when the input signal power is between the upper limit curve (red) and
the lower limit curve (black). At 4 GHz, it exhibits the lowest input sensitivity
due to the fact that the self-oscillation frequency of the first stage divider coincides
with this frequency, so only the relatively lowest input power is required to ensure
the normal operation of the divider.
Fig. 11(a) shows the phase noise test of the output signal in the mode of divide-by-8 with the
1 GHz input clock. The results show that the phase noise is better than -153.7 dBc/Hz
at the 100 kHz frequency offset. Fig. 11(b) shows the phase noise measurement with an input of 16 GHz in the mode of divide-by-8.
The results show that the phase noise is better than -142.1 dBc/Hz with 16 GHz input.
The phase noise characteristics of the signal source R&S FSWP at 1 GHz and 16 GHz
are -148.8, -129.8 dBc/Hz @ 100 kHz offset, respectively. It is known that the
phase noises of both the input signal source and the chip deteriorate with the increase
in frequency. When the circuit works at 16 GHz divide-by-8 mode and is tested with
the direct method, the phase noise deterioration of the chip is less than 5.7 dBc.
Compared with the existing results, the phase noise results at high frequencies are
still excellent.
The total power consumption of the frequency divider core circuit is 39 mW, with a
supply voltage of -3.3 V.
The performance of the proposed frequency divider has been compared with existing
works and is presented in Table 1. For high-frequency dividers, the following FoM definition is usually used to compare
the performance:
$FoM=f_{\mathrm{max}}$/(Power${\times}$f$_{\mathrm{t}})$
where f$_{\mathrm{max}}$ is the highest operating frequency of the frequency divider;
Power is the power consumption of the divider at the highest operating frequency,
and f$_{\mathrm{t}}$ is the cutoff frequency of the device used. Ref [3] and Ref [4] in the table are dynamic frequency dividers, and their operating frequencies cannot
cover low frequencies, so they have an advantage in power consumption. The remaining
works are static structures so that they can operate from low frequencies to high
frequencies. In comparison, the structure presented in this paper can achieve better
FoM values. Meanwhile it also has excellent phase noise performance.
Table 1. Comparison table with previos results
|
Performace
|
Process/ft(GHz)
|
Frequency
(GHz)
|
Division Ration
|
Duty-cycle Adjustment
|
Power
(mW)
|
Supply
(V)
|
Phase Noise
@100 kHz
(dBc/Hz)
|
FoM
|
|
This work
|
0.18 μm SiGe/120
|
0.1-16
|
1-511
|
Yes
|
39
|
3.3
|
-153
|
3.4
|
|
Ref [1]
|
0.18 μm SiGe/200
|
4.7
|
16-159
|
No
|
10.62
|
1.8
|
--
|
2.2
|
|
Ref [3]
|
90 nm CMOS/120
|
10-20
|
2/3
|
No
|
0.339
|
1.2
|
-137
|
491
|
|
Ref [4]
|
55 nm CMOS/220
|
26-44
|
256-508
|
No
|
15.2
|
1.2
|
--
|
13.1
|
|
Ref [7]
|
0.13 μm SiGe/200
|
0.5-20
|
1-31
|
No
|
264
|
3.3
|
-158
|
0.37
|
|
Ref [12]
|
0.35 μm SiGe/43
|
1-12
|
16-(219-1)
|
No
|
--
|
3.3
|
--
|
--
|
Fig. 8. Photograph of programmable frequency chip.
Fig. 9. Test results of 16 GHz input: (a) Divide-by-8; (b) Divide-by-511.
Fig. 10. Test results of input sensitivity @ divide-by-8.
Fig. 11. Measured phase noise @: (a) 1 GHz; (b) 16 GHz input divide-by-8.
V. CONCLUSIONS
This paper proposes an optimized programmable frequency divider that can arbitrarily
expand the frequency division ratio. It integrates the high-speed logic operation
and reset control in the D flip-flop to realize a high-speed 1-511 continuous integer
programmable frequency divider. Its output duty cycle is always close to 50%. The
highest operating frequency is 16 GHz, and the lowest sensitivity is better than -30
dBm. The output signal phase noise is -153.7 dBc/Hz @ 100 kHz offset.
ACKNOWLEDGMENTS
This work is supported by the Natural Science Foundation of Nanjing Vocational
University of Industry Technology (YK21-02-03), the open project of National and Local
Joint Engineering Laboratory of RF Integration and Micro-Assembly Technology (No.
KFJJ20210206), National Natural Science Foundation of China (No. 61804081) and China
Postdoctoral Science Foundation (No. 2018M642292).
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Yang Wang received the B.S. and Ph.D. degrees in School of Electronic and Optical
Engineering from Nanjing University of Science and Technology, Nanjing, China, in
2000 and 2005, respectively. From 2005 to 2020, she was with Nanjing Research Institute
of Electronics Technology, where she worked on radar signal processing and target
recognition. In 2020, she joined School of Electrical Engineering, Nanjing Vocational
University of Industry Technology, China, where she is currently a professor status
high level engineer. Her current research interests include circuit and system, signal
processing and pattern recognition.
Yi Zhang received the B.S. degree in Microelectronics from Soochow University,
Suzhou, China in 2007. He received the Ph.D. degree in Circuit and System from RF&OE-ICs,
School of Information Science and Engineering, Southeast University, Nanjing, China,
in November 2013. In the same year, he joined the faculty of the Department of Microelectronics
Technology, Nanjing University of Posts and Telecommunications, Nanjing, China, where
he is currently an associate professor. His research interests include analog and
mixed signal integrated circuit designs.
Yufeng Guo received the B.S. degree from Sichuan University in 1996. He received
the M.S. degree from the same university in 1999. In June 2005, he received the Ph.D.
degree in Microelectronics from University of Electronic Science and Technology of
China. He is now a Professor and vice president of Nanjing University of Posts and
Telecommunications. His research interests include semiconductor power device, micro/nano
electronics devices, RF and power integrated circuits and systems, wireless energy
transmission and ground penetrating radar design. He owns several awards for teaching
and scientific researches and he is the recipient and co-recipient of the several
best paper rewards. He has published more than 50 papers in his research areas.