ALEX Bitcoin DeFi eliminates liquidation risk through collateral rebalancing pools (CRP) that dynamically shift the balance between risky and risk-less asset in response to market conditions. Our protocol offers both lenders and borrowers more robust returns by smoothing out market “noise” in highly volatile environments.
ALEX’s collateral rebalancing pools (CRP) introduce the concept of portfolio management to DeFi protocols for loanable funds (PLFs). A collateral rebalancing pool can hold more than one asset in the collateral pool. Typically, pools hold two assets. One asset is the risky or “collateral” asset, while the other is the riskless or “loan” asset. This design of collateral pools aims to address the most important problem facing PLFs today: under-collateralization resulting from collateral pool value shrinking significantly during market turmoil
ALEX avoids under-collateralization and thus liquidation risks through algorithmic rebalancing. As market conditions and the prices of the risky and riskless assets change, a collateral pool is automatically rebalanced to prevent under-collateralization. During “risk-on” periods, more relative weight is assigned to the risky asset over the riskless asset. During “risk-off” periods, more relative weight is assigned to the riskless asset over the risky asset. This latter feature ensures that pools cannot become undercollateralized. This dynamic rebalancing, along with other key risk parameters, removes the threat of liquidation. Liquidation often threatens system stability and is extremely costly to market participants. ALEX removes these threats and costs from market participants.
Due to an abundance of caution, ALEX also maintains a reserve fund to deal with black-swan situations. Although limited by design, a collateral pool’s value may drop below the loan’s value. Should this happen, the reserve fund would cover any losses. More detail about this reserve fund, and the collateral rebalancing pool system more broadly, is documented in ALEX’s white paper entitled “Automated Marking Making of Collateral Rebalancing Pool”.
This report below displays the results of both simulated and real datasets. The results show the strength and robustness of our novel approach to collateral pool management. We exploit the results through an agent-based simulation of various market environments, including both momentum and mean-reversion. We also assess its performance on real data during black-swan events, such as when an underlying risky asset declines massively and abruptly. In our tests, the risky asset is BTC, and the riskless asset is USDC.
Key parameters are discussed in detail in our white paper. While some of them are assumed fixed in this report, such as tenor of the fixed rate contract set at three-month, others are studied in more depth to better understand their impact to CRP. Key parameters that are varied include:
We assess performance using the following metrics below, which are functions of the initial LTV and the conversion threshold.
Collateral rebalancing pools, or “CRPs”, serve as an agent (bot) allocating dynamic weights to risky and riskless assets in a collateral pool. To understand the performance of CRPs, we ran several rigorous simulations. In our simulations, we model the risky asset by way of tracking the underlying BTC price. Specifically, we model the price using the standard and widely accepted form of geometric Brownian motion. This includes two key parameters: BTC’s annualized mean μ\muμ and BTC’s implied volatility σ\sigmaσ. These two parameters can be adjusted to reflect various market conditions.
μ\muμ controls market direction. Positive/negative μ\muμ refers to a market with upward/downward momentum, whereas μ\muμ= 0 corresponds to mean reversion in a market without obvious trend. σ\sigmaσ represents a market’s degree of volatility. In conventional finance, implied volatility is derived from observed option prices. However, option markets for crypto-assets are in their infancy and used by a small number of market participants. Therefore, rather than back-calculating implied volatility, we assume it to be the same as historical volatility. In this report, σ\sigmaσ is set to 80%, which is the average historical volatility of the past five years.
Our results are based on 5,000 simulated paths of BTC prices and hourly rebalancing, variously altering initial LTV and conversion threshold parameters. All the key results are described below. Note that the grey area is not relevant in this study — either the conversion threshold is lower than initial LTV or the metrics are not applicable.
Mean-reverting markets refer to markets where no clear trend is observed. Simulating mean-reverting markets suggests that the expected price at maturity is equivalent to the initial price. As future price movements are hard to predict, a mean-reverting market with μ\muμ=0 is the default case when deriving parameters such as option delta.
Performance metrics of the simulated ALEX CRP are presented in Figure 1 below. In summary:
Figure 1: ALEX CRP performance in mean-reverting market conditions — hourly rebalancing
(* Weight is not shown if the conversion rate is < 0.01)
ALEX introduces an innovative system to manage collateral pools with two assets. ALEX’s system is different from other PLFs. Other PLFs use collateral pools that typically consist of a single asset. We refer to collateral pools with a single asset as static pools. If the value of a static pool falls below a pre-determined threshold, a loan is partially or fully liquidated by a third-party liquidator. Such a threshold is called “liquidation threshold” in our analysis.
Liquidation thresholds are comparable to the “conversion threshold” of ALEX, meaning the % value of the LTV at which all of the risky asset is converted into the riskless asset. In addition, the “liquidation rate” for a static pool, which is the percentage of time that liquidation occurs, is also similar to the “conversion rate” of ALEX, which is the percentage of time that all of a risky asset has been converted into the riskless asset.
We set a 5% liquidation penalty in the static pool model. This reflects current practice in other PLFs. The liquidation penalty represents an additional loss to the borrower when the loan is subject to liquidation. For example, AAVE’s liquidation penalty ranges between 5% and 15%, depending on the exact collateral asset. We use a conservative 5% penalty, as $BTC has ample liquidity during normal market conditions.
Figure 2: Static pool performance in mean-reverting market conditions
The performance of the static pool is presented in Figure 2. Comparing the static pool’s performance to that of ALEX’s pool, several insights emerge:
Theoretically, continuous rebalancing is ideal. Continuous rebalancing fully captures all price movements. However, continuous rebalancing is not practically possible. On one hand, data might be affected by short term noise, such as prices bouncing back between bids and asks. On the other hand, there can be confirmation lags when trades are executed on-chain. We therefore model a periodic rather than continuous rebalancing frequency.
Figure 3, below, displays the simulation results when rebalancing daily. As expected, rebalancing hourly (Figure 1) performs better on most metrics, as the system responds more promptly to price movements.
Figure 3: ALEX CRP performance in mean-reverting market conditions — daily rebalancing
(* Weight is not shown if the conversion rate is < 0.01)
Extreme downward market conditions, also called black swan events, refer to unexpected and extreme market movements. Usually, these black swan events lead to large loss to a majority of market participants. Black swan events are a systematic risk that cannot be completely hedged. Although ALEX aims to reduce the impact of black swan events through diversification in the collateral pool, industry-wide issues remain. Two issues are particularly critical: (i) the pool can be insolvent as the unforeseen shock to the market price is largely one-way and substantial; and (ii) liquidity can evaporate swiftly. This is usually accompanied by large price slippages if participants are forced to trade during black swan events. To ALEX pools, trading out of all risky assets might become problematic when liquidity dries up. While the risk is minimized because ALEX pools constantly rebalance, the risk still exists.
We assume an annual return μ\muμ=-200% in the simulation. This is equivalent to a -50% BTC price drop within our contract loan term of three months.
As shown in Figure 4, although conversion rates of 100% of the risky asset to the riskless asset can be high, pools largely remain solvent. The average weight of the risky asset is around 15% at the conversion given initial LTV 75% and conversion LTV 90%. It demonstrates again that the pool faces less pressure at conversion, even during extreme market condition which could dry up liquidity and increase slippage.
Figure 4: ALEX CRP performance under extreme downward market
(* Weight is not shown if the conversion rate is < 0.01)
Due to pandemic and market uncertainty, all risky assets declined sharply in March 2020. On March 12th, 2020, Bitcoin experienced its largest price drop in history — an unprecedented daily change of -49%. How would ALEX’s CRP have performed if the contract had been initiated during this black swan event?
Assume a three-month contract. The contract starts on Mar 1st, 2020. Implied volatility is 80%. The pool rebalances hourly. Initial LTV is set at 75%, and the conversion threshold is set at 90%. The strike price is set to be the spot price at 7,956 — the BTC price on the start day.
ALEX CRP pool would have hit the conversion threshold at 12:00 PM, Mar 12th, 2020, when the remaining BTC in pool, whose relative weight had dropped to 44% in the pool, needed to be converted to USDC. With conversions taking place, the pool would have stayed solvent, and final pool value would have had a 83.16% ratio.
While slippage is essential and should be included in the calculation, it is not easy to quantify in such a scenario. Comparatively, our pressure of converting BTC to USDC would have been lower compared to other PLFs because ALEX would have decreased BTC exposure gradually before the peak of the crisis unfolded.
To complete the report and in contrast with the previous analysis of extreme downward market, we also assess the performance of ALEX CRP during market euphoria. We model market euphoria by assuming an annual return μ\muμ of +200%. This is equivalent to a 50% BTC price increase within our contract term of three months. The simulation results are presented in Figure 5. The results confirm ALEX CRP’s ability in capturing potential upside gains while minimizing the risk of default.
Figure 5: ALEX CRP performance under extreme upward market
(* Weight is not shown if the conversion rate is < 0.01)
This report evaluates the performance of ALEX’s CRP via an agent-based simulation for various market environments under different key parameters. In particular, a stress test is implemented to model black swan events. Taken together, we show that ALEX’s CRP is able to:
In short, ALEX’s protocol delivers a unique and smooth experience to both borrowing and lending activities by minimizing interruption from market noise. Systematic risk still exists and cannot be fully hedged. However, compared to other PLFs, ALEX’s innovative dynamic pool mechanism helps market participants sail smoothly through challenging times and consequently achieve better and more robust returns.