Next Article in Journal
Pareto Optimal Solutions for Network Defense Strategy Selection Simulator in Multi-Objective Reinforcement Learning
Previous Article in Journal
Experimental Investigation on Seismic Behavior of Steel Truss-RC Column Hybrid Structure with Steel Diagonal Braces
Previous Article in Special Issue
Silicon Photonics towards Disaggregation of Resources in Data Centers
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

A 25.78-Gbit/s × 4-ch Active Optical Cable with Ultra-Compact Form Factor for High-Density Optical Interconnects

Hitachi, Ltd. Research & Development Group; Tokyo 185-8601, Japan
*
Author to whom correspondence should be addressed.
Appl. Sci. 2018, 8(1), 137; https://doi.org/10.3390/app8010137
Submission received: 30 October 2017 / Revised: 15 January 2018 / Accepted: 17 January 2018 / Published: 18 January 2018
(This article belongs to the Special Issue Optical Interconnects)

Abstract

:
A 25.78-Gbit/s × 4-ch active optical cable (AOC) with an ultra-compact form factor is proposed. The size of the proposed AOC is 5.2 cm3, which is 55% smaller than the standard form factor of Quad Small Form-factor Pluggable (QSFP28), and 45% smaller than that of Micro Quad Small Form-factor Pluggable (μQSFP). As a result of utilizing a high-efficiency heat-dissipation structure and optimizing signal transmission lines and ground vias, the proposed AOC achieves high-heat dissipation and low-crosstalk characteristics. Furthermore, the proposed AOC demonstrated 25.78-Gbit/s error-free optical transmission over a 100-m Optical Multimode 3 (OM3) multimode fiber under all-channels (4-ch) operation and case temperature (Tc) of 70 °C.

1. Introduction

Recently, with the drastic increase of data traffic in datacenters (DCs) and the evolution of high-performance computing (HPC), high-speed (>25 Gbit/s) data communication are required. In the case of conventional electrical interconnects, high-speed and long distance (>10 m) transmission is challenging due to large transmission loss [1]. On the other hand, optical interconnects have the advantage that high-speed signals can be transmitted further than in an electrical one with low propagation loss. Therefore, as the optical interconnects for rack-to-rack data transmission, active optical cables (AOCs) have been developed and widely applied [2,3,4,5,6]. More recently, for high-density signal transmission, it has become necessary to increase the total input/output (I/O) capacity. To meet that need, we previously proposed a 25.78-Gbit/s × 12-ch AOC in the same size as the form factor of QSFP28 [7]. However, to meet system requirements, 4-ch and 1-ch AOCs are also required.
To achieve high density signal transmission with 4-ch AOCs, it is necessary to reduce the form-factor of AOCs compared with our previous form-factor (12-ch AOC) or the standard form factor of QSFP28 [7,8]. Miniaturizing the form-factor of an AOC, and therefore reducing its surface area, reduces its heat dissipation efficiency. In addition, miniaturizing the form factor also increases crosstalk noise because high-speed signal transmission lines are fabricated closely together. Therefore, to realize 4-ch AOCs with compact form factor, techniques to achieve higher-heat dissipation and lower inter-channel crosstalk have to be improved.
In this study, we developed a 25.78-Gbit/s × 4-ch AOC integrated with a newly ultra-compact form factor. The proposed AOC has a small size of 5.2 cm3 as a result of applying newly developed high-density packaging techniques, namely, a 0.5-mm pitch electrical connector and high-heat dissipation structure. Furthermore, optimizing signal transmission lines and ground vias improved 8inter-channel crosstalk characteristics. In our experiments, the proposed AOC demonstrated 25.78-Gbit/s error-free optical transmission under all-channels (4-ch) operation at high temperature (case temperature: Tc = 70 °C).

2. Structure of Proposed AOC

Figure 1 shows the structure of the proposed AOC. By utilizing a 0.5-mm-pitch electrical connector, which has a 38-pin, and high-density optical assembly technique, the size of the proposed form-factor is 5.2 cm3 (10.9 × 56.6 × 8.4 mm), which is 55% smaller than that of the standard form-factor of “QSFP28” (12.5 cm3: 18.4 × 80.3 × 8.5 mm) [8], and 45% smaller than “μQSFP” (9.4 cm3: 13.8 × 64.9 × 10.6 mm) [9]. A cross-sectional view of the proposed AOC is shown in Figure 1b. In the AOC, a 4-ch vertical cavity surface emitting laser (VCSEL), a 4-ch photodiode (PD), a VCSEL driver integrated circuit (IC), and a transimpedance amplifier (TIA) IC are mounted on the backside of a multi-layer organic substrate. To control the VCSEL driver and the TIA, a micro control unit and an electrically erasable programmable read-only memory (EEPROM) are mounted on the topside of the substrate. An optical connector is placed under the VCSEL and the PD. Thermal vias are fabricated through the substrate to the bottom of the ICs.
In the case of a conventional AOC, the ICs (the VCSEL driver and the TIA) are mounted on the top side of the substrate [3,4,5,6]. On the contrary, the ICs of the proposed AOC are mounted on the bottom side of the substrate. In the latter structure, as shown in Figure 1b, heat directly dissipates to the topside of the case through the thermal vias. Therefore, compared with the conventional AOCs, the proposed AOC structure can suppress deteriorations in the characteristics of the optical devices in a high-temperature environment.

3. Design and Analysis

3.1. Loss Budget of 25.78-Gbit/s Multimode Optical Link

To define the target specification of the proposed AOC, a loss budget of a 25.78-Gbit/s multi mode fiber (MMF) optical link was designed. Figure 2 shows the designed loss budget. Transmitter (Tx) optical power was assumed as that of a VCSEL with minimum optical modulation amplitude (OMA) set to 0 dBm under high-temperature operation at VCSEL temperature of 80 °C. In consideration of optical coupling loss caused by beam spreading from the 25-Gbit/s VCSEL, Tx optical-coupling efficiency between the VCSEL and the MMF was set to −2.0 dB [7]. Receiver (Rx) optical efficiency between the MMF and the 25-Gbit/s PD was set to −1.0 dB [7]. Optical transmission loss of the MMF up to 100 m (including effects of modal and chromatic dispersions on bit-error-rate (BER) power penalty) was set to 1.5 dB. Moreover, considering the performance of the 25-Gbit/s TIA, optical sensitivity of the Rx side was set to −6.0 dBm [7]. The link margin was estimated to be 1.0 dB as shown in Figure 2. This margin is assigned to characteristic variations of components and crosstalk penalty under multi-channel operation.

3.2. Thermal-Via Structure

To assure the proposed AOC has high heat-dissipation efficiency, the structure of the thermal vias was designed and optimized. Figure 3 shows the cross-sectional view of the thermal vias in a multi-layer substrate. The multi-layer substrate consists of eight organic layers with a total thickness of 0.8 mm. Laser via holes (LVHs) and interstitial via holes (IVHs) are located in the build-up layers (with thickness of 0.05 mm/layer) and the core substrate (with thickness of 0.5 mm), respectively. The LVHs are fabricated by laser-beam machining and filled with copper. The IVHs are fabricated by drilling, and their side walls are formed by copper plating and filled with resin. In addition, a thermal sheet is used to fill in the gap between the substrate and the case. By applying and optimizing this heat-dissipation structure, heat directly and efficiently dissipates to the topside of the case through the thermal vias as shown in Figure 3. Therefore, the proposed AOC allows the optical devices to operate higher temperate.

3.3. Inter-Channel Crosstalk

In regard to parallel optical modules, to suppress influence of inter-channel crosstalk, it is important to optimize the design of signal transmission lines and ground vias structures. Figure 4a shows the simulation model to analyze crosstalk by using high-speed communication analysis tool, Keysight ADS. Victim and aggressor lanes are coupled by capacitors, Cx. Crosstalk induced jitter is simulated by changing the capacitance of Cx. Calculated relationship between inter-channel crosstalk jitter and insertion-loss-to-crosstalk ratio (ICR) is plotted in Figure 4b. The ICR was defined as the ratio of the crosstalk and the insertion loss. The result shows that crosstalk jitter can be almost completely suppressed to less than around 0.01 unit interval (UI) when ICR is small of <−35 dB.

4. Fabrication

Based on the design described in Section 3, a prototype of the proposed AOC was fabricated according to the fabrication procedure, shown in Figure 5a–d, simple assembly technique: First, as shown in Figure 5a, optical devices and ICs were mounted on the backside of the substrate by die and wire bonding. The other ICs (micro control unit (MCU) and EEPROM) were mounted on the topside of the substrate. Second, the optical connector and receptacle was aligned above the optical devices by active alignment method. The optical connector consists of 12-ch optical lenses with a pitch of 250 μm and a 12-ch MMF with a 1-mm-thick mechanical transfer (MT) ferrule, and the 4-ch VCSEL and 4-ch PD are aligned with the lenses, simultaneously. Next, the optical connector was fixed onto the substrate by ultraviolet light cure adhesion, and the used master plug connector was removed from the receptacle. Finally, as shown in Figure 5d, they were attached to the case.
Figure 6 shows a photograph of the fabricated AOC. A GaAs- VCSEL and PD, as well as a SiGe- laser diode driver (LDD) and TIA with a clock and data recovery (CDR) circuit are adopted as optical devices and ICs, respectively. Total power consumption of the AOC is about 1.6 W under 4-ch operation with CDR. The breakdown of the AOC’s power consumption is about 20 mW for the VCSEL, 0.7 W for the LDD about 0.8 W for the TIA and 80 mW for the control IC (MCU and EEPROM). The MMF used is an OM3 graded index (GI)-50 μm.

5. Experimental Results

5.1. Heat-Dissipation Characteristics

The temperature of the VCSEL of the fabricated AOC was measured by a thermocouple in a thermostatic chamber with the temperature was controlled so that the case temperature becomes constant at Tc = 70 °C. The measured VCSEL temperature under all-channels (4-ch) operation as shown in Figure 7. This result indicates that the heat-dissipation via structure in the multilayer substrate allows the optical device to operate stably even in a high-temperature environment.

5.2. Crosstalk Characteristics

Signal transmission lines were designed based on the results of the crosstalk analysis in section 3.3. The layout of the signal transmission lines is shown in Figure 8. The pitch of the electrical respectively connector pads is 0.5 mm, width and space of the signal transmission lines are 90 and 120 μm, respectively. The pitch is smaller than of our previous form-factor AOC [7]. Reduction of the pitch leads to an increase of crosstalk between adjacent channels. Therefore, ground vias were provided along each signal transmission line with no gap for electromagnetic field shielding. Figure 9 shows the measured ICR characteristic of a signal transmission line. The measured ICR at the Nyquist frequency (12.89 GHz) is about −53 dB. According to the analysis result shown in Figure 4, that ICR value indicates that crosstalk jitter can be suppressed to less than 0.01 UI.

5.3. 25.78-Gbit/s Optical Signal Transmission

Tx optical and Rx electrical waveforms when all channels (4-ch) are active and transmit in loop-back MMF link are shown in Figure 10. Data rate, amplitude, and pattern length of the input electrical signal were set to 25.78 Gbit/s, 500 mVppd, and 231-1 pseudo-random binary sequence (PRBS), respectively. Bias and modulation currents of the VCSEL were set to 6.5 mA and 8.3 mAp-p, respectively. The measured waveforms show clear eye openings for both the transmitter and receiver at room temperature (Tc = 25 °C) and high temperature (Tc = 70 °C).
Measured bit-error-rate (BER) characteristics for crosstalk are shown in Figure 11. Results show that the measured eye aperture at BER = 10−12 is more than 0.60 UI under all channels (4-ch) operation. The measured crosstalk jitter penalty is smaller than 0.03 UI (between 1-ch and 4-ch operations) in good agreement well with the simulation results shown in Figure 4 and Figure 9.
The BER characteristic of the AOC is shown in Figure 12. The result shows that the AOC demonstrated 25.78-Gbit/s error-free transmission under all channels (4-ch) operation and both at Tc = 25 and 70 °C. According to Figure 12, minimum received optical sensitivities were about −8.3 dBm at Tc = 25 °C and about −9.0 dBm at Tc = 70 °C. The measured BER power penalty is smaller than 0.7 dB under high temperature (Tc = 70 °C). Moreover, the measured BER power penalty less than 1.5 dB for 100-m MMF link was experimentally demonstrated. Minimum received optical sensitivity was about –6.9 dBm over 100-m MMF link under all channels operation and high temperature (Tc = 70 °C). These results indicate that the proposed AOC, with highly efficient heat dissipation, achieved 25.78-Gbit/s operation.

6. Discussion and Conclusions

A 25.78-Gbit/s × 4-ch AOC with an ultra-compact form-factor was proposed and fabricated. As a result of using a 0.5-mm pitch electrical connector, the proposed AOC size is 5.2 cm3. In addition, high heat-dissipation structure and signal transmission lines and ground vias were designed and optimized to guarantee 25.78-Gbit/s error-free optical transmission over 100-m MMF link under all-channels (4-ch) operation and high temperature (Tc = 70 °C). These results indicate that the proposed AOC is applicable to optical interconnects for short-reach optical communication specified in IEEE802.3 standards.
Table 1 shows a bench mark of form factors for 4-ch AOCs. Our newly-proposed ultra-compact form-factor has the smallest size among the form-factors listed. And its transmission density is higher than those of the other standard form factors. In addition, total interface capacity when the proposed form factor is applied in a 19-inch/1-U rack (in two rows) is 7.2 Tbit/s. Therefore, it is concluded that the proposed AOC can provide high-speed and large-capacity rack-to-rack data communication systems in DCs and HPCs.

Author Contributions

Naohiro Kohmu, Toshiaki Takai, Norio Chujo and Hideo Arimoto conceived and designed the proposed AOC. They performed the experiments, and wrote the paper.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Norimatsu, T.; Kawamoto, T.; Kogo, K.; Kohmu, N.; Yuki, F.; Nakajima, N.; Muto, T.; Nasu, J.; Komori, T.; Koba, H.; et al. A 25 Gb/s multistandard serial link transceiver for 50 dB-loss copper cable in 28 nm CMOS. In Proceedings of the IEEE International Solid-State Circuits Conference (ISSCC), San Francisco, CA, USA, 31 January–4 February 2016. [Google Scholar]
  2. Doany, F.E.; Lee, B.G.; Kuchta, D.M.; Rylyakov, A.V.; Baks, C.; Jahnes, C.; Libsch, F.; Schow, C.L. Terabit/sec VCSEL-based parallel optical module based on holey CMOS transceiver IC. J. Lightwave Technol. 2013, 31, 672–680. [Google Scholar] [CrossRef]
  3. Chacinski, M.; Chitica, N.; Molin, S.; Lalic, N.; Sahlén, O. 25.78 Gbps data transmission with 850 nm multimode VCSEL packaged in QSFP form factor module. In Proceedings of the 2013 Optical Fibre Communications Conference (OFC), Anaheim, CA, USA, 17–21 March 2013. Paper OW1B.1. [Google Scholar]
  4. Tsunoda, Y.; Shibasaki, T.; Oku, H.; Ide, S.; Mori, T.; Koyanagi, Y.; Tanaka, K.; Ishihara, T.; Tamura, H. 25.78-Gb/s VCSEL-based optical transceiver with retimer embedded driver and receiver ICs. In Proceedings of the Optical Fiber Communications Conference (OFC), Los Angeles, CA, USA, 22–26 March 2015. Paper Tu3G.4. [Google Scholar]
  5. Tsunoda, Y.; Shibasaki, T.; Oku, H.; Matsui, J.; Shiraishi, T.; Ide, S.; Mori, T.; Koyanagi, Y.; Tamura, H. 24 to 34-Gb/s × 4 multi-rate VCSEL-based optical transceiver with referenceless CDR. In Proceedings of the Optical Fiber Communications Conference (OFC), Anaheim, CA, USA, 20–24 March 2016. Paper Th4D.4. [Google Scholar]
  6. Nagashima, K.; Kise, T.; Ishikawa, Y.; Nasu, H. A Record 1-km MMF NRZ 25.78-Gb/s Error-Free Link Using a 1060-nm DIC VCSEL. IEEE Photonics Technol. Lett. 2016, 28, 418–420. [Google Scholar]
  7. Matsuoka, Y.; Kohmu, N.; Lee, Y.; Arimoto, H.; Takai, T.; Chujo, N.; Sato, M.; Komatsuzaki, S.; Ogura, A.; Yamazaki, K.; et al. A compact 310-Gb/s Optical Transceiver for High-Density Optical Interconnects. IEEE Photonics Technol. Lett. 2017, 29, 334–337. [Google Scholar] [CrossRef]
  8. SFF-8436 Specification for QSFP+ 10 Gbs 4x Pluggable Transceiver. Available online: http://www.optixcom.com/product_pdf/1.duplex/3-QSFP/QSFP_MSA.pdf (accessed on 9 October 2017).
  9. MicroQSFP Multi-Source Agreement (MSA). Available online: http://www.microqsfp.com/ (accessed on 9 October 2017).
Figure 1. Structure of the proposed active optical cable (AOC) (a) whole view and (b) cross sectional view. MMF, multi mode fiber; IC, integrated circuit; VCSEL, vertical cavity surface emitting laser; PD, photodiode; MCU, micro control unit; EEPROM, electrically erasable programmable read-only memory; MT, mechanical transfer; TIA, transimpedance amplifier.
Figure 1. Structure of the proposed active optical cable (AOC) (a) whole view and (b) cross sectional view. MMF, multi mode fiber; IC, integrated circuit; VCSEL, vertical cavity surface emitting laser; PD, photodiode; MCU, micro control unit; EEPROM, electrically erasable programmable read-only memory; MT, mechanical transfer; TIA, transimpedance amplifier.
Applsci 08 00137 g001
Figure 2. Loss budget of 25.78-Gbit/s MMF optical link.
Figure 2. Loss budget of 25.78-Gbit/s MMF optical link.
Applsci 08 00137 g002
Figure 3. Structure of thermal vias in multi-layer substrate.
Figure 3. Structure of thermal vias in multi-layer substrate.
Applsci 08 00137 g003
Figure 4. (a) Simulation model for crosstalk analysis and (b) Calculation result of crosstalk jitter. PRBS, pseudo-random binary sequence.
Figure 4. (a) Simulation model for crosstalk analysis and (b) Calculation result of crosstalk jitter. PRBS, pseudo-random binary sequence.
Applsci 08 00137 g004
Figure 5. Fabrication procedure of proposed AOC. MCU, micro control unit; LDD, laser diode driver.
Figure 5. Fabrication procedure of proposed AOC. MCU, micro control unit; LDD, laser diode driver.
Applsci 08 00137 g005
Figure 6. Photograph of fabricated AOC.
Figure 6. Photograph of fabricated AOC.
Applsci 08 00137 g006
Figure 7. Measured vertical cavity surface emitting laser (VCSEL) temperature.
Figure 7. Measured vertical cavity surface emitting laser (VCSEL) temperature.
Applsci 08 00137 g007
Figure 8. Layout of signal transmission lines and vias.
Figure 8. Layout of signal transmission lines and vias.
Applsci 08 00137 g008
Figure 9. Measured insertion-loss-to-crosstalk ratio (ICR) characteristic.
Figure 9. Measured insertion-loss-to-crosstalk ratio (ICR) characteristic.
Applsci 08 00137 g009
Figure 10. Measured waveforms (a) Tc = 25 °C and (b) Tc = 70 °C.
Figure 10. Measured waveforms (a) Tc = 25 °C and (b) Tc = 70 °C.
Applsci 08 00137 g010
Figure 11. Measured bath-tub curve.
Figure 11. Measured bath-tub curve.
Applsci 08 00137 g011
Figure 12. Measured bit-error-rate (BER) characteristics. NRZ, non-return to zero.
Figure 12. Measured bit-error-rate (BER) characteristics. NRZ, non-return to zero.
Applsci 08 00137 g012
Table 1. Benchmark of form-factors for 4-ch active optical cables (AOCs).
Table 1. Benchmark of form-factors for 4-ch active optical cables (AOCs).
ItemUnitQSFP28 [8]μQSFP [9]This Work
Sizecm312.59.45.2
Transmission densityGbit/s/cm38.211.019.8
Total interface capacity (19-inch/1U rack)Tbit/s3.64.87.2

Share and Cite

MDPI and ACS Style

Kohmu, N.; Takai, T.; Chujo, N.; Arimoto, H. A 25.78-Gbit/s × 4-ch Active Optical Cable with Ultra-Compact Form Factor for High-Density Optical Interconnects. Appl. Sci. 2018, 8, 137. https://doi.org/10.3390/app8010137

AMA Style

Kohmu N, Takai T, Chujo N, Arimoto H. A 25.78-Gbit/s × 4-ch Active Optical Cable with Ultra-Compact Form Factor for High-Density Optical Interconnects. Applied Sciences. 2018; 8(1):137. https://doi.org/10.3390/app8010137

Chicago/Turabian Style

Kohmu, Naohiro, Toshiaki Takai, Norio Chujo, and Hideo Arimoto. 2018. "A 25.78-Gbit/s × 4-ch Active Optical Cable with Ultra-Compact Form Factor for High-Density Optical Interconnects" Applied Sciences 8, no. 1: 137. https://doi.org/10.3390/app8010137

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop